CN211844678U - Magnetic adsorption type wall-climbing robot chassis and magnetic adsorption type wall-climbing robot - Google Patents

Magnetic adsorption type wall-climbing robot chassis and magnetic adsorption type wall-climbing robot Download PDF

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Publication number
CN211844678U
CN211844678U CN202020167252.4U CN202020167252U CN211844678U CN 211844678 U CN211844678 U CN 211844678U CN 202020167252 U CN202020167252 U CN 202020167252U CN 211844678 U CN211844678 U CN 211844678U
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chassis
module
climbing robot
adsorption type
magnetic adsorption
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CN202020167252.4U
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Chinese (zh)
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贾针
贾德增
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Zhengzhou Xunbu Intelligent Technology Co Ltd
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Zhengzhou Xunbu Intelligent Technology Co Ltd
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Abstract

The utility model relates to a wall robot is climbed to magnetism adsorption type and wall robot is climbed to magnetism adsorption type. The chassis comprises a chassis module, wherein the chassis module comprises a base, at least two rollers, a wheel carrier, a power motor and a steering motor; the number of the wheel frames is the same as that of the rollers, and the wheel frames are rotatably assembled on the base and used for mounting the rollers; the roller is a magnetic roller and/or the base is provided with a magnet for attracting the wall surface climbed by the chassis to provide an adsorption force for the base; the rotation axes of the wheel carriers are coplanar; the power motor is used for driving at least one roller to rotate; the steering motor is used for driving each wheel frame to rotate so as to realize the steering of each roller; when the chassis walks, the axes of the rollers are parallel or overlapped; the chassis module is equipped with one, and perhaps the chassis module is equipped with more than two, the base swing joint of adjacent chassis module to make each gyro wheel can paste the wall that the chassis climbed tightly. The chassis is used for solving the problem that the magnetic adsorption type wall-climbing robot in the prior art is poor in adaptability.

Description

Magnetic adsorption type wall-climbing robot chassis and magnetic adsorption type wall-climbing robot
Technical Field
The utility model relates to a wall robot is climbed to magnetism adsorption type and wall robot is climbed to magnetism adsorption type.
Background
The magnetic adsorption type wall-climbing robot is widely applied to various industries to survey, clean and other works in places where workers are difficult to reach, and the wall-climbing principle is that rollers of the robot are set to be magnetic rollers, and the robot is made to climb on the wall surface of a cylindrical structure made of ferromagnetic materials by utilizing the magnetic adsorption effect of the magnetic rollers. Magnetic adsorption formula wall climbing robot generally includes the chassis, the chassis includes the base, the magnetism gyro wheel passes through the wheel carrier and installs on the base, the wheel carrier rotates the assembly on the base, to some robots that only set up the rotation axis coplane of the wheel carrier that two magnetism gyro wheels and two magnetism gyro wheels correspond, can set up a magnetism gyro wheel generally and be the directive wheel, when needing the robot to turn to, control directive wheel turns to, and then drive another magnetism gyro wheel and turn to, this kind of robot is when climbing cylindric structure, because cylindric structure's periphery is the curved surface, so in the robot turns to the in-process, the condition of base slope appears very easily, if the object of taking of robot does not allow the slope, then this robot will not accomplish the task.
SUMMERY OF THE UTILITY MODEL
The utility model aims to provide a magnetic adsorption type wall-climbing robot chassis, which is used for solving the problem that the magnetic adsorption type wall-climbing robot in the prior art has poor adaptability because the base can incline in the steering process; the utility model also provides an use the magnetism adsorption type wall climbing robot on above-mentioned magnetism adsorption type wall climbing robot chassis.
The utility model provides a wall climbing robot chassis of magnetism adsorption type adopts following technical scheme:
this magnetism adsorbs formula wall climbing robot chassis includes the chassis module, and the chassis module includes:
a chassis module base;
at least two chassis module rollers;
the chassis module wheel carriers are the same as the chassis module idler wheels in number, are rotatably assembled on the chassis module base and are used for installing the chassis module idler wheels;
the chassis module roller is a magnetic roller and/or a magnet is arranged on a chassis module base and is used for mutually attracting a wall surface climbed by the chassis of the magnetic adsorption type wall-climbing robot to provide adsorption force for the chassis module base;
the rotating axes of the wheel carriers of the chassis modules are coplanar;
the power motor is used for driving at least one chassis module roller to rotate;
the steering motor is used for driving the wheel carrier of each chassis module to rotate so as to realize the steering of the roller of each chassis module;
when the chassis of the magnetic adsorption type wall-climbing robot walks, the axes of the rollers of the chassis modules are parallel or overlapped;
the chassis module is equipped with one, perhaps the chassis module is equipped with more than two, the chassis module base swing joint of adjacent chassis module to make each chassis module gyro wheel can paste the wall that the wall climbing robot chassis of close magnetic adsorption formula climbed.
The utility model provides a magnetic adsorption type wall climbing robot chassis's beneficial effect is: each chassis module roller in the chassis module of the robot chassis can actively steer, and when the direction of the robot chassis needs to be changed, each chassis module roller actively steers, so that the chassis module base of the chassis module can not incline in the process that the robot chassis continues to advance, a robot using the robot chassis can carry carried objects which are not allowed to incline, and the adaptability is strong; in addition, when the robot chassis comprises more than two chassis modules, the chassis module bases of the chassis modules are movably connected, so that the robot chassis can normally walk on the curved wall surface with the changed curvature.
Further, the chassis module bases of adjacent chassis modules are hinged. This connection is simple.
Further, magnetism adsorbs formula wall climbing robot chassis still includes single round auxiliary module, and single round auxiliary module includes auxiliary module base, auxiliary module gyro wheel and auxiliary module wheel carrier, and auxiliary module base is articulated with chassis module base, and the assembly is rotated on auxiliary module base to the auxiliary module wheel carrier for install auxiliary module gyro wheel: the auxiliary module roller is provided with a magnet on the magnetic roller and/or the auxiliary module base, so that the auxiliary module roller and the wall surface climbed by the magnetic adsorption type wall-climbing robot base can attract each other to provide adsorption force for the auxiliary module base. The single-wheel auxiliary module is arranged, so that the magnetic adsorption type wall-climbing robot chassis is more stable in use. Furthermore, the number of the power motors in each chassis module is the same as the number of the rollers of the chassis module and corresponds to the number of the rollers of the chassis module one by one. The arrangement is convenient for driving the rollers of each chassis module.
Further, magnets on the chassis module base are disposed between adjacent chassis module rollers. Set up like this, the wall is comparatively even to the adsorption affinity distribution of magnet for it is more stable when the robot chassis climbing.
Furthermore, the number of the steering motors is the same as that of the chassis module rollers, and the steering motors correspond to the chassis module rollers one by one. The arrangement is convenient for the steering control of the chassis module roller.
Furthermore, the magnetic adsorption type wall-climbing robot chassis further comprises a controller used for controlling synchronous action of the steering motors. The arrangement can improve the steering efficiency of the rollers of the chassis modules of the robot chassis, and further improve the movement efficiency of the robot chassis.
Further, the arrangement direction of two adjacent chassis modules is perpendicular to the arrangement direction of the wheel carriers of the two chassis modules on the chassis modules. The arrangement is more stable when the robot using the robot chassis carries goods.
The utility model provides a wall robot is climbed to magnetism adsorption type adopts following technical scheme:
this magnetism adsorbs formula wall climbing robot includes chassis and the functional device mount pad of setting on the chassis, and the chassis includes the chassis module, and the chassis module includes:
a chassis module base;
at least two chassis module rollers;
the chassis module wheel carriers are the same as the chassis module idler wheels in number, are rotatably assembled on the chassis module base and are used for installing the chassis module idler wheels;
the chassis module roller is a magnetic roller and/or a magnet is arranged on a chassis module base and is used for mutually attracting a wall surface climbed by the chassis of the magnetic adsorption type wall-climbing robot to provide adsorption force for the chassis module base;
the rotating axes of the wheel carriers of the chassis modules are coplanar;
the power motor is used for driving at least one chassis module roller to rotate;
the steering motor is used for driving the wheel carrier of each chassis module to rotate so as to realize the steering of the roller of each chassis module;
when the chassis of the magnetic adsorption type wall-climbing robot walks, the axes of the rollers of the chassis modules are parallel or overlapped;
the chassis module is equipped with one, perhaps the chassis module is equipped with more than two, the chassis module base swing joint of adjacent chassis module to make each chassis module gyro wheel can paste the wall that the wall climbing robot chassis of close magnetic adsorption formula climbed.
The utility model provides a magnetic adsorption type wall climbing robot's beneficial effect is: each chassis module roller in the chassis module of the robot can actively steer, and when the direction of the robot needs to be changed, each chassis module roller actively steers, so that the chassis module base of the chassis module cannot incline in the process that the robot continues to advance, the robot can carry carried objects which are not allowed to incline, and the adaptability is strong; in addition, when the robot comprises more than two chassis modules, the chassis module bases of the chassis modules are movably connected, so that the robot can normally walk on the curved wall surface with the changed curvature.
Further, the chassis module bases of adjacent chassis modules are hinged. This connection is simple.
Further, magnetism adsorbs formula wall climbing robot chassis still includes single round auxiliary module, and single round auxiliary module includes auxiliary module base, auxiliary module gyro wheel and auxiliary module wheel carrier, and auxiliary module base is articulated with chassis module base, and the assembly is rotated on auxiliary module base to the auxiliary module wheel carrier for install auxiliary module gyro wheel: the auxiliary module roller is provided with a magnet on the magnetic roller and/or the auxiliary module base, so that the auxiliary module roller and the wall surface climbed by the magnetic adsorption type wall-climbing robot base can attract each other to provide adsorption force for the auxiliary module base. The magnetic adsorption type wall-climbing robot is more stable when in use due to the arrangement of the single-wheel auxiliary module.
Furthermore, the number of the power motors in each chassis module is the same as the number of the rollers of the chassis module and corresponds to the number of the rollers of the chassis module one by one. The arrangement is convenient for driving the rollers of each chassis module.
Further, magnets on the chassis module base are disposed between adjacent chassis module rollers. Set up like this, the wall is comparatively even to the adsorption affinity distribution of magnet for it is more stable when the robot scrambles.
Furthermore, the number of the steering motors is the same as that of the chassis module rollers, and the steering motors correspond to the chassis module rollers one by one. The arrangement is convenient for the steering control of the chassis module roller.
Furthermore, the magnetic adsorption type wall-climbing robot chassis further comprises a controller used for controlling synchronous action of the steering motors. The arrangement can improve the steering efficiency of the rollers of each chassis module in the robot, and further improve the motion efficiency of the robot.
Further, the arrangement direction of two adjacent chassis modules is perpendicular to the arrangement direction of the wheel carriers of the two chassis modules on the chassis modules. The arrangement is adopted, so that the robot is more stable when carrying goods.
Drawings
Fig. 1 is a three-dimensional view of a magnetic adsorption type wall-climbing robot chassis when the chassis travels in a cylinder axial direction on an outer circumferential surface of a cylinder in embodiment 1 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention;
fig. 2 is a front view of the magnetic adsorption type wall-climbing robot chassis in the embodiment 1 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention, when the magnetic adsorption type wall-climbing robot chassis travels on the outer peripheral surface of the cylinder in the axial direction of the cylinder;
fig. 3 is a left side view of the magnetic adsorption type wall-climbing robot chassis in the embodiment 1 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention, when the magnetic adsorption type wall-climbing robot chassis travels along the axial direction of the cylinder on the outer circumferential surface of the cylinder;
fig. 4 is a three-dimensional view of the magnetic adsorption type wall-climbing robot chassis in the embodiment 1 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention, which travels on the outer circumferential surface of the cylinder in the direction perpendicular to the axial direction of the cylinder;
fig. 5 is a front view of the magnetic adsorption type wall-climbing robot chassis in embodiment 1 of the magnetic adsorption type wall-climbing robot chassis according to the present invention, which travels on the outer circumferential surface of the cylinder in a direction perpendicular to the axial direction of the cylinder;
fig. 6 is a left side view of the magnetic adsorption type wall-climbing robot chassis in the embodiment 1 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention, when the magnetic adsorption type wall-climbing robot chassis travels on the outer peripheral surface of the cylinder in a direction perpendicular to the axial direction of the cylinder;
fig. 7 is a three-dimensional view of the magnetic adsorption type wall-climbing robot chassis walking in an obliquely upward direction on the outer peripheral surface of the cylinder in embodiment 1 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention;
fig. 8 is a three-dimensional view of the magnetic adsorption type wall-climbing robot chassis when the chassis travels in the axial direction of the cylinder on the outer peripheral surface of the cylinder in embodiment 2 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention;
fig. 9 is a three-dimensional view of the magnetic adsorption type wall-climbing robot chassis in embodiment 2 of the magnetic adsorption type wall-climbing robot chassis according to the present invention, which travels on the outer circumferential surface of the cylinder in a direction perpendicular to the axial direction of the cylinder;
fig. 10 is a three-dimensional view of embodiment 3 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention;
fig. 11 is a three-dimensional view of embodiment 4 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention;
fig. 12 is a three-dimensional view of the magnetic adsorption type wall-climbing robot chassis when the chassis travels in the axial direction of the cylinder on the outer peripheral surface of the cylinder in embodiment 5 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention;
fig. 13 is a three-dimensional view of the magnetic adsorption type wall-climbing robot chassis when walking along the direction perpendicular to the axial direction of the cylinder on the outer peripheral surface of the cylinder in embodiment 5 of the magnetic adsorption type wall-climbing robot chassis provided by the present invention.
In the figure: 1-chassis module, 2-cylinder, 11-base, 12-roller, 13-wheel carrier, 14-power motor, 15-steering motor, 16-permanent magnet; 101-chassis module, 102-hinge, 103-cylinder, 104-roller; 3-a steering motor, 4-a wheel carrier rotating shaft and 5-a synchronous transmission belt; 6-roller, 7-base, 8-power motor, 9-steering motor; 105-cylinder, 106-chassis module, 107-hinge, 108-single wheel auxiliary module, 109-auxiliary module base, 110-auxiliary module wheel carrier, 111-auxiliary module roller, 112-steering motor, 113-roller.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention, i.e., the described embodiments are only some, but not all embodiments of the invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.
Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiment of the present invention, all other embodiments obtained by the person skilled in the art without creative work belong to the protection scope of the present invention.
It is noted that relational terms such as "first" and "second," and the like, may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.
The features and properties of the present invention are described in further detail below with reference to examples.
The utility model provides an embodiment 1 on magnetic adsorption formula wall climbing robot chassis:
in this embodiment, the magnetic adsorption type wall-climbing robot chassis only includes one chassis module.
As shown in fig. 1-3, the chassis module 1 includes a base 11, the base 11 is generally T-shaped and includes two wing plates and a separating body located on the same side of the two wing plates, a wheel carrier 13 is rotatably mounted on each of the two wing plates of the base 11, the two wheel carriers 13 are respectively disposed on two sides of the separating body, and the rotation axes of the two wheel carriers 13 are parallel to each other; the two wheel frames 13 are provided with rollers 12, and the rollers 12 are magnetic rollers; two wheel carriers 13 are respectively provided with a power motor 14, and the output shaft of the power motor 14 is directly connected with the rotating shaft of the roller 12 and is used for driving the roller 12 to rotate; one side of each wing plate, which is opposite to the separating body, is provided with a steering motor 15, the steering motors 15 are rotating motors, and output shafts of the two steering motors 15 are respectively in transmission connection with rotating shafts of the two wheel frames 13 and are used for driving the wheel frames 13 to rotate, so that the steering of the two rollers 12 is realized; the chassis 11 forms a chassis module chassis of the chassis module 1, the wheel carrier 13 forms a chassis module wheel carrier of the chassis module 1, and the rollers 12 form chassis module rollers of the chassis module 1.
The chassis module 1 is further provided with a controller (not shown in the figure) for controlling the two steering motors 15 to act, the controller controls the two steering motors 15 to act synchronously, and controls the steering and rotating angles of the two wheel frames 13 to be the same, so that the steering and rotating angles of the two rollers 12 are the same, and the axes of the two rollers 12 are parallel or overlapped when the chassis module 1 runs.
As shown in fig. 1 to 3, the chassis module 1 in the present embodiment is used to climb on the outer circumferential surface of a cylinder 2, and the cylinder 2 is a cylinder made of ferromagnetic material and has a cylindrical shape.
As shown in fig. 1-3, a permanent magnet 16 is fixedly mounted on one side of the partition body of the base 11 close to the cylinder 2, and the permanent magnet 16 and the cylinder 2 attract each other to provide the chassis module 1 with an adsorption force towards the cylinder 2, which can make the chassis module 1 more stable when walking.
This chassis module 1's two gyro wheels 12 all dispose steering motor 15, and steering motor 15 is under the control of controller, can two gyro wheels 12 of synchro control turn to, in chassis module 1 walking process, when chassis module 1 need turn to, can make two gyro wheels 12 turn to simultaneously, so, the base 11 of walking chassis module 1 on bent shape wall just can not take place the slope, then the robot that uses this chassis just can carry the thing of taking that does not allow the slope, adaptability is stronger.
The chassis shown in fig. 1 to 3 described above travels on the outer peripheral surface of the cylinder 2 in the axial direction of the cylinder 2, and in this state, the axes of the two rollers 12 of the chassis module 1 are perpendicular to the axis of the cylinder 2; the chassis shown in fig. 4 to 6 travels on the outer peripheral surface of the cylinder 2 in a direction perpendicular to the axial direction of the cylinder 2, in which state the axes of the two rollers 12 of the chassis module 1 are parallel to the axis of the cylinder 2; the chassis shown in fig. 7 travels in an obliquely upward direction on the outer peripheral surface of the cylinder 2, and in this state, the axes of the two rollers 12 of the chassis module 1 and the axis of the cylinder 2 spatially form an acute angle.
The utility model provides an embodiment 2 on magnetic adsorption formula wall climbing robot chassis:
as shown in fig. 8 and 9, in this embodiment, the magnetic adsorption type wall-climbing robot chassis includes three chassis modules 101, and the structure of the three chassis modules 101 is the same as that of the chassis module 1 in embodiment 1 of the magnetic adsorption type wall-climbing robot chassis described above, and details are not repeated here.
The chassis in this embodiment climbs on the outer peripheral surface of the cylinder 103, and the cylinder 103 is a cylinder made of ferromagnetic material and is cylindrical; the bases of three chassis modules 101 are connected together by hinges 102 to allow hinging of adjacent chassis modules 101.
The chassis is formed by combining the chassis modules 101, so that a robot using the chassis can provide large carrying capacity to adapt to a working condition with high requirement on the carrying capacity.
The chassis shown in fig. 8 travels on the outer peripheral surface of the cylinder 103 in the axial direction of the cylinder 103, and the axes of the rollers 104 of the three chassis modules 101 are perpendicular to the axis of the cylinder 103. The chassis shown in fig. 9 travels on the outer peripheral surface of the cylinder 103 in a direction perpendicular to the axial direction of the cylinder 103, and the axes of the rollers 104 of the three chassis modules 101 are parallel to the axis of the cylinder 103.
The utility model provides an embodiment 3 on magnetic adsorption formula wall climbing robot chassis:
the difference from example 1 is that: as shown in fig. 10, the wheel frame rotating shafts 4 of the two wheel frames extend out from one side of the wing plate, which faces away from the separating body, the chassis module is provided with only one steering motor 3, the steering motor 3 is installed on the base, and the axis of the output shaft of the steering motor is parallel to the axis of the two wheel frame rotating shafts 4, the steering motor 3 drives the two wheel frame rotating shafts 4 to rotate through the synchronous transmission belt 5, so as to realize the synchronous steering of the two wheel frames.
The utility model provides an embodiment 4 on magnetic adsorption formula wall climbing robot chassis:
the difference from example 1 is that: as shown in fig. 11, the chassis module is provided with three rollers 6, the three rollers 6 are mounted on a base 7 through corresponding wheel carriers, the three wheel carriers are rotatably mounted on the base 7, the rotation axes of the three wheel carriers are coplanar, two separators are arranged on the base 7 to separate the three rollers 6, the three rollers 6 are respectively provided with a steering motor 9 to realize the steering of the three rollers, the three steering motors 9 in the embodiment are connected through the control of a controller to realize the synchronous rotation of the three wheel carriers, the two rollers 6 on two sides are provided with power motors 8, and the roller 6 in the middle is not provided with the power motor 8 to form a driven wheel.
The utility model provides an embodiment 5 on magnetic adsorption formula wall climbing robot chassis:
as shown in fig. 12 and 13, in this embodiment, the chassis of the magnetic adsorption type wall-climbing robot includes a chassis module 106 and a single-wheel auxiliary module 108, and the structure of the chassis module 106 is the same as that of the chassis module 1 in embodiment 1 of the chassis of the magnetic adsorption type wall-climbing robot, and is not described herein again.
As shown in fig. 12 and 13, the single-wheel auxiliary module 108 includes an auxiliary module base 109, an auxiliary module wheel frame 110 is rotatably assembled on the auxiliary module base 109, the auxiliary module wheel frame 110 is used for installing an auxiliary module wheel 111, the auxiliary module wheel 111 is a magnetic wheel, a steering motor 112 for driving the auxiliary module wheel frame 110 to rotate is installed on the auxiliary module base 109, and the steering motor 112 drives the auxiliary module wheel frame 110 to rotate to realize the rotation of the auxiliary module wheel 111. The controller in the chassis module 106 is in control connection with the steering motor 112 in the single-wheel assist module 108 to achieve the same steering and rotation angles of the assist module wheel carrier 110 in the single-wheel assist module 108 and the two wheel carriers in the chassis module 106.
As shown in fig. 12 and 13, the auxiliary module base 109 of the single-wheel auxiliary module 108 and the base of the chassis module 106 are connected together by hinges 107 to enable articulation of the single-wheel auxiliary module 108 with the chassis module 106. The base plate in this embodiment climbs on the outer peripheral surface of the cylinder 105, and the cylinder 105 is a cylinder made of ferromagnetic material and is cylindrical.
The chassis shown in fig. 12 travels on the outer circumferential surface of the cylinder 105 in the axial direction of the cylinder 105, the axes of the two rollers 113 in the chassis module 106 are perpendicular to the axis of the cylinder 105, and the axes of the auxiliary module rollers 111 in the single-wheel auxiliary module 108 are also perpendicular to the axis of the cylinder 105; the chassis shown in fig. 13 travels on the outer circumferential surface of the cylinder 105 in a direction perpendicular to the axial direction of the cylinder 105, the axes of the two rollers 113 in the chassis module 106 are parallel to the axis of the cylinder 105, and the axes of the auxiliary module rollers 111 in the single-wheel auxiliary module 108 are also parallel to the axis of the cylinder 105.
In the above embodiment 2, the adjacent chassis modules are hinged together by hinges. In other embodiments, other structures may be provided between adjacent chassis modules, each chassis module is hinged with other structures, and the same may be used, and the other structures may be single-wheel auxiliary modules in embodiment 5 described above.
In the above embodiment 5, the single-wheel auxiliary module is provided with a steering motor to drive the auxiliary module to steer the roller. In other embodiments, the single-wheel auxiliary module may not have a steering motor, and the auxiliary module roller moves along with the movement of the chassis module and turns along with the movement direction of the chassis module, and the same can be used.
In the above embodiment 5, the roller of the single-wheel auxiliary module is a magnetic roller, and the single-wheel auxiliary module is attracted to the outer circumferential surface of the cylinder through the magnetic roller. In other embodiments, the single-wheel auxiliary module can be adsorbed on the cylinder in other manners, if the permanent magnet is arranged on the auxiliary module base, the single-wheel auxiliary module can be adsorbed on the cylinder through the permanent magnet, and under the condition, the auxiliary module roller can be set into a magnetic roller or a non-magnetic roller, and can be used.
In the above embodiments 1 to 5, the rollers in each chassis module are magnetic rollers, the base is provided with a permanent magnet, and each chassis module is adsorbed on the cylinder through the magnetic rollers and the permanent magnet. In other embodiments, only the roller may be a magnetic roller without a permanent magnet, or only the permanent magnet may be disposed on the base and the roller may be a non-magnetic roller, so that the chassis module may be attached to the cylinder.
In the above embodiments 1, 2, 3 and 5, the chassis module is provided with two rollers. In other embodiments, three, four or more rollers may be provided on the chassis module, and the same may be used, but of course, when more than three rollers are provided on the chassis module, the rotation axes of the corresponding three wheel carriers need to be coplanar.
In the above embodiment 4, three rollers are provided in the chassis module, and a driven wheel is provided in the middle of the three rollers, and no power motor is provided. In other embodiments, the roller in the middle of the three rollers may be provided with a power motor, and the same can be used.
In the above embodiments 1, 2, 3 and 5, each roller in the chassis module is provided with a power motor. In other embodiments, a power motor may be configured for only one roller, that is, the other roller serves as a driven wheel, and the same can be used; for the case that the number of the rollers is more than two, the number of the power motors can be determined according to the actual situation, if three rollers exist, the power motor can be arranged only on the middle roller, and the other two rollers are driven wheels and can also be used.
In the above embodiments 1-5, the permanent magnets are mounted on the side of the partition of the base of the chassis module that faces the cylinder when in use. In other embodiments, the permanent magnet can be installed at other positions, such as the side faces of the two wing plates facing the cylinder, and the permanent magnet can also be used; the permanent magnets may also be replaced by electromagnets and the same may be used.
In the above embodiments 1, 2 and 5, each roller in the chassis module is provided with a steering motor. In other embodiments, a steering motor may be configured for the two rollers, the two wheel carriers are in transmission connection through a connecting rod, when the steering motor drives one wheel carrier to rotate, the other wheel carrier rotates along with the steering motor, and the rotating angle and the rotating direction are the same; of course, the two wheel carriers can be driven to rotate simultaneously through a gear train matched with a steering motor and can also be used; in other embodiments, a steering motor may also be provided, and the steering motor is respectively connected to the two wheel frames through a link mechanism, so as to drive the two wheel frames to rotate.
In the above embodiment 4, one steering motor is provided for each of the three rollers. In other embodiments, a steering motor may be configured for three rollers, the three wheel carriers are in transmission connection through a connecting rod, when the steering motor drives one wheel carrier to rotate, the other two wheel carriers rotate along with the steering motor, and the rotating angles and directions are the same; of course, three wheel carriers can be driven to rotate simultaneously through a gear train matched with a steering motor, and the steering motor can also be used; in other embodiments, a steering motor may also be provided, and the steering motor is connected to the three wheel frames through a link mechanism, so as to drive the three wheel frames to rotate.
In the above embodiments 1 to 5, the steering motor of the chassis module is directly connected to the rotating shaft of the wheel frame to drive the rotation of the wheel frame, and the steering motor rotates the motor. In other embodiments, the steering motor may also be a linear motor, and the linear motor is connected with the wheel carrier through a link mechanism, so as to realize the rotation of the wheel carrier, and the same may also be used.
In the above embodiments 1 to 5, the output shaft of the power motor in the chassis module is directly connected to the rotating shaft of the roller to drive the roller to rotate. In other embodiments, the transmission between the output shaft of the power motor and the rotating shaft of the roller may also be realized through other transmission structures, for example, the transmission structure may be a gear or a synchronous belt.
In the above embodiments 1 to 5, the rollers in the chassis module are synchronized by the controller controlling the steering motors. In other embodiments, one steering motor may first control one roller to steer, and then the other steering motors may control the corresponding roller to steer, which may also be used.
In the above embodiments 1 to 5, the power motor of the chassis module is a built-in hub motor, an inner stator of the hub motor is connected to the wheel carrier, and a rotor of the hub motor is connected to the roller, so as to drive the roller to rotate.
In the above embodiment 2, each chassis module is provided with a controller to control the rotation of the two steering motors, and the chassis includes three chassis modules, and three controllers are provided to control the six steering motors. In other embodiments, only one controller may be provided in the chassis, and the control of six steering motors by one controller may also be used.
In the above examples 2 and 5, the chassis climbed on the cylinder. In other embodiments, the chassis can also climb on other structures, such as curved wall, conical barrel etc. when the chassis climbs on the barrel structure that external diameter changes like conical barrel or other curved wall that camber changes, because articulated together through the hinge between each chassis module (between chassis module and the single round auxiliary module), so can guarantee that the gyro wheel in each chassis module (gyro wheel in the chassis module and the auxiliary module gyro wheel in the single round auxiliary module) all can normally contact with the wall that it climbed to stability when having guaranteed the chassis and climbing.
In the above embodiment 2, the adjacent chassis modules are hinged together by hinges. In other embodiments, the adjacent chassis modules may be hinged together by other structures, for example, a connecting rod is respectively arranged on the base of the adjacent chassis modules, and the overhanging ends of the two connecting rods are hinged together by a hinged shaft, which can also be used.
In the above embodiment 5, the chassis module and the single-wheel auxiliary module are hinged together by the hinge. In other embodiments, the chassis module and the single-wheel auxiliary module may be hinged together by other structures, for example, a connecting rod is respectively arranged on the base of the chassis module and the base of the auxiliary module of the single-wheel auxiliary module, and the overhanging ends of the two connecting rods are hinged together by a hinge shaft, which can also be used.
In other embodiments, the magnetic adsorption type wall-climbing robot chassis can be provided with a gyroscope control system for maintaining a balanced posture when the chassis transversely spirals around the cylinder (i.e. the roller axis rotates 90 degrees, rotates from a horizontal extension state to a vertical extension state), and does not incline due to inertia. Gyroscope control systems are prior art and will not be described in great detail herein. Of course, in other embodiments, no matter the magnetism adsorbs formula wall climbing robot scrambles on the drum or on vertical plane, when the walking of two gyro wheels arrangement direction of perpendicular to in the magnetism adsorption formula wall climbing robot chassis or walking direction and gyro wheel arrangement direction contained angle are less than 90 degrees, all can improve the stability of the operation of robot through gyroscope control system.
The utility model provides a wall robot is climbed to magnetism absorption formula still, this wall robot is climbed to magnetism absorption formula include the chassis and set up the functional device mount pad on the chassis, and functional device mount pad is used for installing such as functional device such as sensor, and the structure on chassis is the same with the structure on chassis in each embodiment on above-mentioned magnetism absorption formula wall robot chassis, and here is no longer repeated.
The above description is only for the preferred embodiment of the present invention, and the present invention is not limited thereto, the protection scope of the present invention is defined by the claims, and all structural changes equivalent to the contents of the description and drawings of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. Magnetic adsorption type wall climbing robot chassis, characterized by, including the chassis module, the chassis module includes:
a chassis module base;
at least two chassis module rollers;
the chassis module wheel carriers are the same as the chassis module idler wheels in number, are rotatably assembled on the chassis module base and are used for installing the chassis module idler wheels;
the chassis module roller is a magnetic roller and/or a magnet is arranged on a chassis module base and is used for mutually attracting a wall surface climbed by the chassis of the magnetic adsorption type wall-climbing robot to provide an adsorption force for the chassis module base;
the rotating axes of the wheel carriers of the chassis modules are coplanar;
the power motor is used for driving at least one chassis module roller to rotate;
the steering motor is used for driving the wheel carrier of each chassis module to rotate so as to realize the steering of the roller of each chassis module;
when the chassis of the magnetic adsorption type wall-climbing robot walks, the axes of the rollers of the chassis modules are parallel or overlapped;
the chassis module is provided with one, or the chassis module is provided with more than two, the chassis module base swing joint of adjacent chassis module to make each chassis module gyro wheel can paste the wall that the wall climbing robot chassis of magnetic adsorption formula climbed.
2. The magnetic adsorption type wall-climbing robot chassis of claim 1, wherein the chassis module bases of adjacent chassis modules are hinged.
3. The magnetic adsorption type wall-climbing robot chassis of claim 1, further comprising a single-wheel auxiliary module, the single-wheel auxiliary module comprising:
the auxiliary module base is hinged with the chassis module base;
an auxiliary module roller;
the auxiliary module wheel carrier is rotatably assembled on the auxiliary module base and used for mounting an auxiliary module roller;
the auxiliary module roller is provided with a magnet on the magnetic roller and/or the auxiliary module base, so that the auxiliary module roller and the wall surface climbed by the magnetic adsorption type wall-climbing robot base can attract each other to provide adsorption force for the auxiliary module base.
4. The magnetic adsorption type wall-climbing robot chassis according to claim 1, 2 or 3, wherein the number of the power motors in each chassis module is the same as the number of the rollers of the chassis module and corresponds to one another.
5. A magnetic attraction wall-climbing robot chassis according to claim 1, 2 or 3, in which magnets on the chassis module base are arranged between adjacent chassis module rollers.
6. The magnetic adsorption type wall-climbing robot chassis according to claim 1, 2 or 3, wherein the number of the steering motors is the same as that of the chassis module rollers and corresponds to one another.
7. The magnetic adsorption type wall-climbing robot chassis according to claim 6, further comprising a controller for controlling the synchronous motion of the steering motors.
8. The magnetic adsorption type wall-climbing robot chassis as claimed in claim 1, 2 or 3, wherein the arrangement direction of two adjacent chassis modules is perpendicular to the arrangement direction of the wheel carriers of the two chassis modules on the chassis module.
9. The magnetic adsorption type wall climbing robot comprises a chassis and a functional device mounting seat arranged on the chassis, and is characterized in that the chassis is the magnetic adsorption type wall climbing robot chassis in any one of claims 1 to 8.
CN202020167252.4U 2020-02-13 2020-02-13 Magnetic adsorption type wall-climbing robot chassis and magnetic adsorption type wall-climbing robot Active CN211844678U (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113232732A (en) * 2021-06-16 2021-08-10 燕山大学 Crawler-type wall climbing robot with curved surface self-adaption capability
CN114906245A (en) * 2021-02-07 2022-08-16 郑州迅布智能科技有限公司 Wall-climbing robot

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114906245A (en) * 2021-02-07 2022-08-16 郑州迅布智能科技有限公司 Wall-climbing robot
CN113232732A (en) * 2021-06-16 2021-08-10 燕山大学 Crawler-type wall climbing robot with curved surface self-adaption capability

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