CN215155131U - Hinge type wall climbing robot capable of realizing multi-angle/discontinuous wall surface transition - Google Patents

Abstract

The utility model relates to a hinge type wall climbing robot capable of realizing multi-angle/discontinuous wall transition, which comprises two vehicle bodies and a hinge module, wherein the two vehicle bodies are connected together through the hinge module; the hinge module provides the front vehicle body with three rotational degrees of freedom relative to the rear vehicle body. The hinge module mainly includes: the front connecting rod is connected with the front connecting rod; the front vehicle body movement angle is limited to (-35 to-35); the movable angle of the rear vehicle body is limited to (+35 to 47); the movable angle between the front connecting rod and the rear connecting rod is limited to (-45 degrees to-45 degrees). The robot has the characteristics of high modularization degree, small volume, light weight, flexible posture adjustment, strong curved surface adaptability, good obstacle crossing capability and high integration level.

Description

Hinge type wall climbing robot capable of realizing multi-angle/discontinuous wall surface transition

Technical Field

The utility model relates to a robotechnology specifically is to provide a hinge type wall climbing robot that can realize multi-angle/discontinuous wall transition.

Background

With the continuous promotion of globalization, the demand for large-scale manufacturing of large components such as large ships and heavy machinery is increasing, and the large components may have defects in the manufacturing and using processes, and the defects may seriously affect the quality of the components and even bring about safety problems. In the conventional detection and fault diagnosis, workers need to operate by means of instruments, and the conventional detection and fault diagnosis has the disadvantages of narrow operation space, poor working environment and high danger. The permanent magnetic adsorption type wall-climbing robot has large adsorption force due to magnetic adsorption and does not need power supply driving, thereby being widely applied to the operation environment with the wall surface made of magnetic conductive materials. The existing wall-climbing robot has poor curved surface adaptability, inflexible action and excessively complex structure, so the application environment is limited.

Patent document "a crawler type wall climbing robot (CN208731086U) capable of adapting to various curved surfaces" discloses a wall climbing robot, which comprises a vehicle body module and a crawler belt module. The problem exists that the connecting mechanism is complex, the walking is slow, the small turning radius can not be realized, and the connecting mechanism can not pass through the wall surface when multi-angle/discontinuous wall surface transition occurs. Patent document "a hinge mechanism, mechanical device, and wall-climbing robot (CN 209586934U)" provides a hinge mechanism including a hinge base and a rotation block. The hinge structure has only one degree of freedom, can only realize rotation in one direction, and has a greatly limited use scene.

In summary, although the existing wall-climbing robot can adapt to walking on a plane and has a certain obstacle-crossing function, the existing wall-climbing robot lacks a flexible connecting mechanism, is inflexible in turning, has poor curved surface adaptive capacity, and cannot perform multi-angle/discontinuous wall surface transition, particularly cannot pass through a right-angle wall surface transition position; in addition, the hinge connection mechanism in the above-mentioned patent publication is relatively complex in structure and also insufficient in degree of freedom, and can be further structurally optimized according to the functional requirements of the wall-climbing robot. The utility model discloses a hinge type wall climbing robot has been developed to these problems. The robot system consists of two vehicle bodies and hinge modules, can be self-adaptive to different operation curved surfaces, and has the advantages of high modularization degree, simple and light structure, flexible movement and strong environment adaptability.

SUMMERY OF THE UTILITY MODEL

To the not enough of prior art, the utility model discloses the technical problem who plans to solve is: the hinge type wall climbing robot has the advantages of being high in modularization degree, small in size, light in weight, flexible in posture adjustment, strong in curved surface adaptability, good in obstacle crossing capability and high in integration level.

The multi-angle in this application refers to different wall transition department, has certain contained angle between two walls, for example right angle or obtuse angle, and the contained angle between two walls that this robot can cross is not fixed, is in a scope. Discontinuity is defined as the transition between two walls that do not produce a line of intersection, for example, the transition between two parallel walls that are spaced less apart.

The utility model provides a technical scheme is:

a hinge type wall climbing robot capable of realizing multi-angle/discontinuous wall surface transition comprises two vehicle bodies and a hinge module, wherein the two vehicle bodies are connected together through the hinge module; characterized in that the hinge module provides the front body with three rotational degrees of freedom relative to the rear body.

The vehicle body mainly includes: the device comprises a front vehicle body upper plate, a front vehicle body bottom plate, a front vehicle body front plate, a front vehicle body rear plate, vehicle body side plates, a rear vehicle body upper plate, a rear vehicle body bottom plate, a rear vehicle body front plate, a rear vehicle body rear plate, a stepping motor, a motor reducer, wheels, a data transmission module, a picture transmission module and a singlechip; the front vehicle body upper plate (301), the front vehicle body rear plate (302), the front vehicle body bottom plate (303), the front vehicle body front plate (304) and the two vehicle body side plates (103) form a frame of a front vehicle body, and the rear vehicle body upper plate (101), the rear vehicle body rear plate (102), the rear vehicle body bottom plate (104), the rear vehicle body front plate (105) and the two vehicle body side plates (103) form a frame of a rear vehicle body;

taking a rear vehicle body as an example, the rear vehicle body upper plate (101), the rear vehicle body rear plate (102), the rear vehicle body bottom plate (104), the rear vehicle body front plate (105) and the vehicle body side plate (103) are connected through screws to form a closed box body, namely a frame of the wall surface transition hinge robot rear vehicle body (1), and the stepping motor is connected with the motor reducer (106) through bolts; the motor reducer (106) is fixed on a rear vehicle body side plate 103, and an output shaft of the motor reducer is connected with a wheel (109) in a key connection mode; the frame and the internal parts of the front vehicle body (3) are basically the same as those of the rear vehicle body (1), except that the image transmission module (305) is arranged on the front vehicle body, and the data transmission module (108) is arranged on the rear vehicle body;

the image transmission module is a video image transmitting end, transmits the received video image to a display in the hand of an operator through wireless remote transmission via an image transmission module receiving end, and the operator watches the surrounding environment condition of the vehicle body according to the received video image; the data transmission module is a receiving end and is used for receiving a control instruction sent by an operator and then transmitting instruction data to the single chip microcomputer; the single chip microcomputer is arranged in the frame of the rear vehicle body and used for receiving a data instruction of the data transmission module and then controlling the stepping motor to make corresponding action; the wheel is a wheel with multiple functions and can be replaced by wheels with different attributes, for example, a magnetic wheel with magnetic adsorption capacity can be used on a metal wall surface, and the wheels with adhesion property can be replaced on other non-metal wall surfaces to ensure the adsorption capacity of the wall surfaces.

The hinge module mainly includes: front vehicle body connecting piece, front connecting rod, back vehicle body connecting piece.

The rear vehicle body connecting piece is connected with a front plate of a rear vehicle body through a screw, the connection is rigid connection, the rear connecting rod is connected with the rear vehicle body connecting piece in a hinged mode in the horizontal longitudinal direction, and the axis of a hinged hole is parallel to the ground, so that pitching motion around an X axis is formed between the two vehicle bodies; the front vehicle body connecting piece is connected with a rear plate of the front vehicle body through a screw, the connection is rigid connection, and the front connecting rod is connected with the front vehicle body connecting piece in a copper bush mode in the horizontal transverse direction, so that a rolling motion around a Y axis is formed between the two vehicle bodies; the front and rear connecting rods are connected in a hinged mode in the vertical direction, so that the two vehicle bodies have a yaw motion around the Z axis. The hinge module is a structure with three degrees of freedom, and ensures that the robot can stably walk across multi-angle/discontinuous wall transition positions or on a curved surface with larger curvature.

The forward direction of the vehicle body is the positive direction of the Y axis, the upward direction of the vertical wall is the positive direction of the Z axis, and the positive direction of the X axis is determined according to a Cartesian coordinate rule; the moving angle of the front vehicle body is limited to (-35 degrees to +35 degrees); the movable angle of the rear vehicle body is limited to (+35 degrees to +47 degrees); the movable angle between the front connecting rod and the rear connecting rod is limited to (-45 degrees- +45 degrees).

Compared with the prior art, the utility model discloses a hinge type wall climbing robot has following innovation point:

1. the utility model discloses the modularization degree is high, compact structure, and is small, and is light simple, convenient to carry has quick dead lock structure (for example connect with the part of steel ball bolt this type) between three big structures of preceding automobile body, back automobile body, hinge simultaneously, conveniently dismantles the installation through the pin joint mode. The small-volume modular design facilitates operation inside a large storage tank, for example, when the inner wall of a boiler is detected, the four structures of the front vehicle body, the rear vehicle body, the wheels and the hinges are disassembled firstly and are sent by workers one by one, and then the rapid assembly is carried out inside the boiler and finally the operation is carried out, so that the installation time is greatly reduced by the rapid locking structure, and the working efficiency is improved;

2. the utility model discloses connect together with the hinge module between two automobile bodies, have certain interval between two automobile bodies, because single automobile body occupation space is little, the crossing speed is fast, generally preceding automobile body passes through earlier when turning, hinder more, multi-angle/discontinuous wall transition, the back automobile body passes through again, the hinge module makes the adjustment of motion gesture between two automobile bodies nimble in this process, environmental suitability is strong, turning radius is littleer, has good ability of hindering more;

3. the utility model discloses a hinge module has three degree of freedom, and preceding automobile body connecting piece has the degree of freedom of rolling about the Y axle with preceding connecting rod junction, and preceding connecting rod has the degree of freedom of rolling about the Z axle with back connecting rod junction, and back automobile body connecting piece has the degree of freedom of every single move about the X axle with back connecting rod junction. The self-adaptive capacity of the wall-climbing robot to the change of the curvature of the wall surface in the operation process can be realized under the coordination of three degrees of freedom, particularly, when the wall surface is in multi-angle/discontinuous transition, the vehicle body can rotate around an X axis in a self-adaptive manner between the rear vehicle body connecting piece and the rear connecting rod in the movement process to form a certain rotation angle, and the front vehicle body and the rear vehicle body can be ensured to be in contact with the wall surface so as to smoothly pass through. In addition, when the vehicle body turns, the front connecting rod and the rear connecting rod in the hinge module rotate for a certain angle around the Z axis at the joint of the front connecting rod and the rear connecting rod, so that the turning radius of the robot is smaller, and the robot can pass through more easily in narrow places. The hinge module also provides guarantee for the obstacle crossing capability of the robot, and solves the problem that the robot cannot pass through the hinge module when encountering multi-angle/discontinuous wall surface transition in the prior art;

4. the wheels in the utility model are used as an independent structure and have replaceability, and the robot can use wheels with different attributes according to different operation scenes, for example, the wheels can be replaced by magnetic wheels with magnetic adsorption capacity when metal wall surfaces such as large-scale vertical storage tanks and ships perform wall climbing movement operation; when working on other wall surfaces such as the ground, the wheel made of the adhesive bonding material can be replaced.

5. The utility model discloses in divide into the automobile body two parts, reuse hinge module connects between, only two wheels on every automobile body, preceding automobile body contains the picture and passes the module, back automobile body contains the data transmission module, the hinge module also is the rotation that has the three degree of freedom of XYZ, the wall transition of multi-angle can be realized to this kind of connected mode of hinge module, automobile body after the part can successively pass through in wall right angle transition department respectively, thereby also can adapt to the metal wall of different curvatures through the angle between connecting rod and preceding automobile body connecting piece (and preceding automobile body be rigid connection) before adjusting.

Drawings

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

FIG. 2 is a top view of the overall assembly of the present invention;

FIG. 3 is a schematic view of the overall structure of the interior of the vehicle body;

FIG. 4 is a top view of the vehicle body interior structure;

FIG. 5 is a schematic structural view of a hinge module;

FIG. 6 is a schematic view of an installation structure of a limiting chute and a limiting column;

FIG. 7 is a schematic longitudinal cross-sectional view of the connection location of the front and rear links of FIG. 5;

FIG. 8 is an exemplary diagram of a turn during the exercise of the present invention;

fig. 9 is an illustration of the present invention when performing a right angle male transition;

fig. 10 is an illustration of the present invention when performing a reentrant right angle transition;

FIG. 11 is a schematic view of the present invention during single-wheel obstacle crossing;

in the figure: 1 rear vehicle body, 2 hinge modules, 3 front vehicle body, 101 rear vehicle body upper plate, 301 front vehicle body upper plate, 102 rear vehicle body rear plate, 302 front vehicle body rear plate, 103 vehicle body side plate, 104 rear vehicle body bottom plate, 105 rear vehicle body front plate, 303 front vehicle body bottom plate, 304 front vehicle body front plate, 106 motor reducer, 107 stepping motor, 108 data transmission module, 109 wheels, 305 image transmission module, 201 rear vehicle body connecting piece, 202 rear connecting rod, 203 front connecting rod, 204 front vehicle body connecting piece, 205 end cover, 206 lining shaft, 207 copper sleeve, 01 limit chute and 02 limit column.

Detailed Description

The present invention will be further described with reference to the following embodiments and the accompanying drawings. The scope of protection of the application is not limited to the embodiments described.

Definition of XYZ coordinate axes: the forward direction of the vehicle body is the positive direction of the Y axis, the upward direction of the vertical wall is the positive direction of the Z axis, and the positive direction of the X axis is determined according to a Cartesian coordinate rule. The X-axis rotation is used for providing freedom degree for the robot car body module to pass through steps by a single wheel, the angle of a front car body is limited to (-35 degrees to +35 degrees), and the purpose is to prevent the car body module from reversing 180 degrees to change the position of the wheel and influence the motion of the robot; the X-axis direction rotation on the rear vehicle body is used for providing a change allowance for the length direction of the whole vehicle body of the robot, can adapt to the vehicle body change of the robot during various wall surface transitions, and the angle is limited to (+35 degrees to +47 degrees), so that the mutual constraint of two vehicle bodies is realized at the limit position, namely, when the internal corner transitions, the rear vehicle body module provides an auxiliary force for the front vehicle body module to help the front vehicle body module to complete the transition, and the front vehicle body completes the transition and then utilizes the hinge to provide a traction force for the rear vehicle body to realize the transition of the rear vehicle body; the Z-axis direction rotation of the middle joint of the hinge mainly improves the flexible movement capability of the robot, reduces the turning radius of the robot, limits the angle to (-45 degrees to +45 degrees), and aims to prevent the two magnetic wheels from adsorbing and influencing the movement of the front and rear car bodies in the turning process.

The quick locking mechanism refers to a connecting mechanism between the hinge and the front and rear vehicle body modules, and is mainly connected by using parts such as steel ball bolts, so that quick and safe installation and locking are realized.

A hinge-type wall-climbing robot for wall surface transition, as shown in fig. 1, includes a rear vehicle body (1), a hinge module (2), and a front vehicle body (3). The front vehicle body (3) and the rear vehicle body (1) are identical in appearance but different in internal structure, and are connected through the hinge module (2) to form the whole wall-climbing robot structure.

As shown in fig. 2, 3 and 4, the body of the hinge-type wall-climbing robot mainly comprises a front body upper plate (301), a front body rear plate (302), a front body bottom plate (303), a front body front plate (304), a body side plate (103), a rear body upper plate (101), a rear body rear plate (102), a rear body bottom plate (104), a rear body front plate (105), a stepping motor (107), a motor reducer (106), wheels (109), a data transmission module (108), a map transmission module (305) and a single chip microcomputer; the front vehicle body upper plate (301), the front vehicle body rear plate (302), the front vehicle body bottom plate (303), the front vehicle body front plate (304) and the two vehicle body side plates (103) form a frame of a front vehicle body, and the rear vehicle body upper plate (101), the rear vehicle body rear plate (102), the rear vehicle body bottom plate (104), the rear vehicle body front plate (105) and the two vehicle body side plates (103) form a frame of a rear vehicle body.

As shown in fig. 2, 3 and 4, for example, the rear vehicle body is a closed box body formed by connecting a rear vehicle body upper plate (101), a rear vehicle body rear plate (102), a rear vehicle body bottom plate (104), a rear vehicle body front plate (105) and a vehicle body side plate (103) through screws, that is, a frame of the rear vehicle body (1) of the wall transition hinge robot, and the stepping motor (107) is connected with a motor reducer (106) through bolts; the motor reducer (106) is fixed on a rear vehicle body side plate 103, and an output shaft of the motor reducer is connected with a wheel (109) in a key connection mode; the wheel (109) can be replaced by wheels with different attributes, and can be replaced according to the use environment, for example, a magnetic wheel with magnetic adsorption capacity can be used on a metal wall surface; the frame and the internal parts of the front vehicle body (3) are basically the same as those of the rear vehicle body (1), except that the image transmission module (305) is arranged on the front vehicle body, and the data transmission module (108) is arranged on the rear vehicle body;

the image transmission module (305) is arranged in a frame of the front vehicle body and is fixed on a vehicle body upper plate (301) of the front vehicle body through a screw, the image transmission module (305) in the front vehicle body is a video image transmitting end, the video image is transmitted to a display in the hand of an operator through wireless remote transmission, and the operator can watch the surrounding environment condition of the vehicle body according to the video image transmitting end; the data transmission module (108) is arranged in a frame of the rear vehicle body and is fixed to an upper plate (101) of the rear vehicle body through a screw, and the data transmission module is a receiving end and is used for receiving a control instruction sent by a transmitting end in the hand of an operator and then transmitting the instruction data to the single chip microcomputer; the single chip microcomputer is arranged in the frame of the rear vehicle body and used for receiving data instructions of the data transmission module (108) and then controlling the stepping motor (107) to make corresponding actions. The number of the single-chip microcomputer is one, and an STC51 single-chip microcomputer can be selected. The image transmission module is a module capable of transmitting video images, such as a 2.4G wireless WIFI video real-time transmission module LC328, and the data transmission module may use a module similar to the wireless data transmission module SRWF-108.

As shown in fig. 5, the hinge module of the wall transition hinge robot mainly includes: a rear vehicle body connecting piece (201), a rear connecting rod (202), a front connecting rod (203) and a front vehicle body connecting piece (204). Fig. 5 shows the shape structure of the part, which is used for connecting the front and rear vehicle bodies and has three degrees of freedom rotation after being combined into one piece.

The rear vehicle body connecting piece (201) is connected with a front plate (105) of the rear vehicle body through a screw, the connection is rigid connection, the rear connecting rod (202) is connected with the rear vehicle body connecting piece (201) in a hinged mode in the horizontal longitudinal direction, and the axis of a hinged hole is parallel to the ground, so that the front vehicle body and the rear vehicle body can rotate around the X axis in a pitching mode; the front vehicle body connecting piece (204) is connected with a front vehicle body rear plate (302) through a screw, the connection is rigid connection, and the front connecting rod (203) is connected with the front vehicle body connecting piece (204) in a copper bush mode, so that a roll rotation around a Y axis is formed between the front vehicle body and the rear vehicle body; the front connecting rod (203) and the rear connecting rod (202) are connected in a hinged mode in the vertical direction, the axis of a hinged hole is perpendicular to the ground, therefore, the front vehicle body and the rear vehicle body can rotate in a transverse swinging mode around the Z axis, and the axis of the hinged hole is perpendicular to the ground. The hinge module (2) is a structure with three degrees of freedom, and the robot can stably walk across a multi-angle/discontinuous wall surface transition position or on a curved surface with a large curvature degree.

The rear vehicle body connecting piece (201) is provided with a plane mounting plate and two lug seats which are symmetrically and vertically fixed on the plane mounting plate, the plane mounting plate and the rear vehicle body are fixed together through a quick dismounting structure, the two lug seats are kept horizontal to the ground at the moment, the two lug seats are provided with threaded holes, and the axes of the threaded holes are in the X direction;

one end of the rear connecting rod 202 is provided with a protruding part with a through hole, the protruding part can extend into a space between two lug seats of the rear vehicle body connecting piece and is hinged with the lining shaft 206 through the copper sleeve 207, and meanwhile, the axial positions of the copper sleeve and the lining shaft are limited by the end covers 205 at two sides, so that the protruding part of the rear connecting rod can rotate relative to the X axis; the convex part is also provided with a limiting sliding groove, a limiting shaft (which can be replaced by a long screw) is arranged at the position of the corresponding limiting sliding groove on the lug seat of the rear vehicle body connecting piece 201, the limiting shaft can move in the range of the limiting sliding groove, and the movable angle of the rear connecting rod relative to the rear connecting rod connecting piece can be limited to +35 degrees to +47 degrees.

Referring to fig. 7, the other end of the rear connecting rod 202 is provided with two lug seats, the lug seats are respectively provided with a countersunk through hole and a threaded hole at the upper and lower ends, the countersunk through hole and the threaded hole are used for fixing a long screw to serve as a limiting shaft, the axes of the countersunk through hole and the threaded hole are parallel to the Z axis, one end of the front connecting rod 203 is provided with a protruding part with a through hole, the protruding part can extend into a space between the two lug seats of the rear connecting rod and is hinged with the lining shaft through a copper bush, so that the rear connecting rod 202 and the front connecting rod 203 can swing around the Z axis, the protruding part is also provided with a limiting sliding groove, and the limiting sliding groove is matched with a limiting shaft (the long screw) fixed on the rear connecting rod, and can limit the range of the moving angle of the front connecting rod relative to the rear connecting rod to-45 ° - +45 °.

A limiting structure of a combination of a limiting chute and a limiting shaft is also arranged between the other end of the front connecting rod 203 and the front vehicle body connecting piece 204, so that the range of the movable angle between the front connecting rod and the front vehicle body connecting piece is-35 degrees to +35 degrees.

The utility model discloses work flow in practical application is:

basic motion process of the moving vehicle body: the stepping motor (107) on the front vehicle body is set to be in the advancing direction, the stepping motor (107) on the rear vehicle body is also set to be in the advancing direction, each wheel on the front vehicle body and the rear vehicle body is driven by one stepping motor, then the speed is set, the four stepping motors on the vehicle body have the same rotating speed, and the advancing motion of the hinge-machine type wall climbing person is realized; the stepping motor (107) on the front vehicle body is set to be in a backward direction, meanwhile, the stepping motor (107) on the rear vehicle body is also set to be in the backward direction, then the speed is set, the same rotating speed is provided for 4 stepping motors on the vehicle body, and the backward movement of the hinge type wall climbing robot is realized; the vehicle body is turned by using a differential principle, and in a forward state, when the rotating speed of a left stepping motor (107) is high, the vehicle body is turned to the right; when the rotating speed of the stepping motor (107) on the right side is high, the left rotation of the vehicle body is realized.

Basic control process of moving vehicle body: in the operation process, an operator can remotely control the vehicle body through a remote controller in a hand or use a mouse, a keyboard and the like to give a control instruction through a human-computer interaction interface, the data instruction is transmitted to the data transmission module in a wireless mode, the data transmission module (108) receives an instruction signal and then transmits the instruction signal to the single chip microcomputer, and the single chip microcomputer controls the stepping motor (107) to drive the vehicle body to walk. Meanwhile, an operator continuously sends data instructions to a data transmission module (108) in the rear car body in a wireless mode through operating a remote controller or a human-computer interaction interface according to real-time video pictures fed back by the picture transmission module (305), and then the motion speed and direction of the robot are adjusted in real time through the single chip microcomputer control stepping motor (107), so that accurate control is achieved.

Basic motion process when the moving vehicle body makes a turn: as shown in fig. 8, taking the front vehicle body (3) as an example, firstly setting two stepping motors (107) of the front vehicle body as the advancing direction, then setting the speed, setting the rotating speeds of the stepping motors (107) at the two sides of the rear vehicle body (1) to be the same, and setting the relatively higher rotating speed of the stepping motor (107) at the left side of the front vehicle body (3) and the relatively lower rotating speed of the stepping motor (107) at the right side of the front vehicle body (3) by taking the rotating speeds as the reference and utilizing the differential principle, so as to realize the right turning process of the front vehicle body (3); in the process, the front vehicle body (3) has a certain deflection angle relative to the rear vehicle body (1), specifically, the front connecting rod (203) in the hinge module (2) rotates right around the Z axis relative to the rear connecting rod (202) to generate a certain deflection angle, so that the right-turning motion of the whole vehicle is realized, and meanwhile, a smaller turning radius is also realized.

The basic motion process of the movable vehicle body during the external corner right-angle transition is as follows: as shown in fig. 9, the wheels 109 are magnetic wheels, the adsorption capacity of the magnetic wheels ensures that the vehicle body stably crawls on a vertical wall surface, when the robot encounters an external corner right-angle transition on the wall surface, because the hinge module (2) has a certain length distance, the front vehicle body (3) firstly passes through the right-angle turning part to reach a horizontal wall surface, and the rear vehicle body (1) then passes through; in the process, the hinge module (2) performs pitching motion relative to the rear vehicle body (1) to generate a certain deflection angle, and specifically, a rear connecting rod (202) in the hinge module (2) rotates around an X axis relative to a rear vehicle body connecting piece (201) to generate a certain deflection angle; meanwhile, the rear end of the front vehicle body (3) can sink, the front end of the rear vehicle body (1) can sink, and the front vehicle body (3) has a certain pulling force effect on the rear vehicle body (1).

The basic motion process of the movable vehicle body during reentrant right-angle transition is as follows: as shown in fig. 10, when the robot encounters a reentrant right-angle transition on the wall surface, because the hinge module (2) has a certain length distance, the front vehicle body (3) firstly passes through the right-angle turning point to reach the vertical wall surface, the adsorption capacity of the magnetic wheels ensures that the vehicle body stably crawls on the vertical wall surface, and the rear vehicle body (1) passes through; in the process, the hinge module (2) performs pitching motion relative to the rear vehicle body (1) to generate a certain deflection angle, and specifically, a rear connecting rod (202) in the hinge module (2) rotates around an X axis relative to a rear vehicle body connecting piece (201) to generate a certain deflection angle; meanwhile, the rear end of the front vehicle body (3) has a certain upward pitching trend, the front end of the rear vehicle body (1) also has a certain upward pitching trend, and the rear vehicle body (1) has a certain thrust effect on the front vehicle body (3). In the process, the rear body attachment 201 is rigidly connected to the rear body, and the rear body attachment 201 will then tend to tilt forward with the front link 203 and the front body attachment 204 substantially stationary.

The basic motion process of the moving vehicle body during single-wheel obstacle crossing: as shown in fig. 11, the robot travels in a straight line and suddenly meets an obstacle in front, and when the robot does not avoid the obstacle, the front vehicle body (3) rotates a certain angle relative to the hinge module (2) in the process that the right wheel of the front vehicle body (3) passes over the obstacle, specifically, the front vehicle body connecting piece (204) in the hinge module (2) rotates a certain angle around the Y axis relative to the front connecting rod (203), and the rear vehicle body (1) is still on the horizontal plane and cannot deflect due to the fact that the hinge module (2) has a certain length distance; in the process that the rear vehicle body (1) passes through the obstacle, the rear vehicle body (1) can rotate for a certain angle relative to the front vehicle body (3), specifically, a front connecting rod (203) in the hinge module (2) rotates for a certain angle around a Y axis relative to a front vehicle body connecting piece (204), and the rear vehicle body respectively restores to the position in the balance process after passing through the obstacle.

The utility model discloses the nothing is mentioned the part and is applicable to prior art.

Claims (6)

1. A hinge type wall climbing robot capable of realizing multi-angle/discontinuous wall surface transition comprises two vehicle bodies and a hinge module, wherein the two vehicle bodies are connected together through the hinge module; characterized in that the hinge module provides the front body with three rotational degrees of freedom relative to the rear body.

2. A wall-climbing robot as recited in claim 1, wherein the vehicle body mainly includes: the device comprises a front vehicle body upper plate, a front vehicle body bottom plate, a front vehicle body front plate, a front vehicle body rear plate, vehicle body side plates, a rear vehicle body upper plate, a rear vehicle body bottom plate, a rear vehicle body front plate, a rear vehicle body rear plate, a stepping motor, a motor reducer, wheels, a data transmission module, a picture transmission module and a singlechip; the front vehicle body upper plate (301), the front vehicle body rear plate (302), the front vehicle body bottom plate (303), the front vehicle body front plate (304) and the two vehicle body side plates (103) form a frame of a front vehicle body, and the rear vehicle body upper plate (101), the rear vehicle body rear plate (102), the rear vehicle body bottom plate (104), the rear vehicle body front plate (105) and the two vehicle body side plates (103) form a frame of a rear vehicle body;

taking a rear vehicle body as an example, the rear vehicle body upper plate (101), the rear vehicle body rear plate (102), the rear vehicle body bottom plate (104), the rear vehicle body front plate (105) and the vehicle body side plate (103) are connected through screws to form a closed box body, namely a frame of the wall surface transition hinge robot rear vehicle body (1), and the stepping motor (107) is connected with the motor reducer (106) through bolts; the motor reducer (106) is fixed on a rear vehicle body bottom plate 104, and an output shaft of the motor reducer is connected with wheels (109) in a key connection mode; the drawing transmission module (305) is arranged on the front vehicle body, and the data transmission module (108) is arranged on the rear vehicle body; the wheels have multiple functions and can be changed into wheels with different attributes according to the reality;

the image transmission module is a video image transmitting end and transmits the received video image to a display in the hand of an operator through a wireless remote transmission and an image transmission module receiving end; the data transmission module is a receiving end; the single chip microcomputer is arranged in the frame of the rear vehicle body and used for receiving data instructions of the data transmission module and then controlling the stepping motor to make corresponding actions.

3. The wall-climbing robot of claim 1, wherein the hinge module mainly comprises: the front connecting rod is connected with the front connecting rod;

the rear vehicle body connecting piece is connected with a front plate of a rear vehicle body through a screw, the connection is rigid connection, the rear connecting rod is connected with the rear vehicle body connecting piece in a hinged mode in the horizontal longitudinal direction, and the axis of a hinged hole is parallel to the ground, so that pitching motion around an X axis is formed between the two vehicle bodies; the front vehicle body connecting piece is connected with a rear plate of the front vehicle body through a screw, the connection is rigid connection, and the front connecting rod is connected with the front vehicle body connecting piece in a copper bush mode in the horizontal transverse direction, so that a rolling motion around a Y axis is formed between the two vehicle bodies; the front and rear connecting rods are connected in a hinged mode in the vertical direction, so that the two vehicle bodies have a yaw motion around the Z axis.

4. A wall-climbing robot as claimed in claim 3, wherein the vehicle body advancing direction is a positive direction of the Y-axis, the vertical wall facing upward direction is a positive direction of the Z-axis, and the positive direction of the X-axis is determined according to a cartesian coordinate criterion; the moving angle of the front vehicle body is limited to (-35 degrees to +35 degrees); the movable angle of the rear vehicle body is limited to (+35 degrees to +47 degrees); the movable angle between the front connecting rod and the rear connecting rod is limited to (-45 degrees- +45 degrees).

5. The wall-climbing robot as claimed in claim 3, wherein the rear vehicle body connecting part (201) has a plane mounting plate and two ear seats symmetrically and vertically fixed on the plane mounting plate, the plane mounting plate and the rear vehicle body are fixed together through a quick-assembly and disassembly structure, the two ear seats are kept horizontal with the ground, the two ear seats have threaded holes, and the axes of the threaded holes are in the X-axis direction;

one end of the rear connecting rod (202) is provided with a protruding part with a through hole, the protruding part can extend into a space between two lug seats of the rear vehicle body connecting piece and is hinged with the lining shaft (206) through the copper sleeve (207), and meanwhile, the axial positions of the copper sleeve and the lining shaft are limited by using end covers (205) at two sides, so that the protruding part of the rear connecting rod can rotate relative to the X axis; the lug boss of the rear vehicle body connecting piece (201) is provided with a limiting sliding groove, a limiting shaft is arranged at a position corresponding to the limiting sliding groove, the limiting shaft can move in the range of the limiting sliding groove, and the movable angle of the rear connecting rod relative to the rear connecting rod connecting piece can be limited to +35 degrees to +47 degrees;

the other end of the rear connecting rod (202) is provided with two lug seats, the upper part and the lower part of each lug seat are respectively provided with a countersunk through hole and a threaded hole, the countersunk through holes and the threaded holes are used for fixing long screws to serve as limiting shafts, the axes of the countersunk through holes and the threaded holes are parallel to a Z shaft, one end of the front connecting rod (203) is provided with a bulge part with a through hole, the bulge part can extend into a space between the two lug seats of the rear connecting rod and is hinged with the lining shaft through a copper sleeve, so that the rear connecting rod (202) and the front connecting rod (203) can swing around the Z shaft, the bulge part is also provided with a limiting sliding groove, and the limiting sliding groove is matched with the limiting shaft fixed on the rear connecting rod, so that the range of the movable angle of the front connecting rod relative to the rear connecting rod can be limited to be-45 degrees to +45 degrees;

a limiting structure combining a limiting chute and a limiting shaft is also arranged between the other end of the front connecting rod (203) and the front vehicle body connecting piece (204), so that the range of the movable angle between the front connecting rod and the front vehicle body connecting piece is-35 degrees to +35 degrees.

6. The wall-climbing robot as recited in claim 1, wherein the hinges and the front and rear body modules are both quickly assembled and disassembled by a quick locking mechanism.

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