Tracked Robot

Abstract

The tracked robot including a rack, two sets of track mechanisms and power components operating respectively in cooperation with the two sets of track mechanisms. Each set of track mechanism includes a track, a driving wheel, a tensioning wheel and a plurality of load bearing wheels, wherein the driving wheel, the tensioning wheel and the load bearing wheels are sleeved with the track, the tensioning wheel is used for tensioning the track, the driving wheel, the tensioning wheel and the load bearing wheels are rotatably arranged on the rack respectively through a driving wheel axle, a tensioning wheel axle and load bearing wheel axles, the driving wheel drives the tensioning wheel and the load bearing wheels to rotate through the track, baffles are arranged on the outer sides of the driving wheel, the tensioning wheel and the plurality of bearing wheels, and the track is embedded between the baffles.

Claims

1. A tracked robot, comprising a rack, two sets of track mechanisms, and power components operating respectively in cooperation with the two sets of track mechanisms, characterized in that each set of track mechanism comprises a track, a driving wheel, a tensioning wheel and a plurality of load bearing wheels, wherein the driving wheel, the tensioning wheel and the load bearing wheels are sleeved with the track, the tensioning wheel is used for tensioning the track, the driving wheel, the tensioning wheel and the load bearing wheels are rotatably arranged on the rack through a driving wheel axle, a tensioning wheel axle and load bearing wheel axles respectively, the driving wheel drives the tensioning wheel and the load bearing wheels to rotate through the track, baffles are arranged on outer sides of the driving wheel, the tensioning wheel and the plurality of load bearing wheels, and the track is embedded between the baffles.

2. The tracked robot according to claim 1, characterized in that the driving wheels are provided with clamping grooves which are matched with shifting teeth inside the tracks to drive the tracks to achieve transmission.

3. The tracked robot according to claim 2, characterized in that the load bearing wheel on one side of the track is provided with a groove matched with the shifting teeth inside the track to achieve transmission, and the tensioning wheel and the other load bearing wheels are respectively composed of two half side wheels.

4. The tracked robot according to claim 2, characterized in that the load bearing wheels on both sides of the track are provided with grooves matched with the shifting teeth inside the track to achieve transmission, and the tensioning wheel and the other load bearing wheels are respectively composed of two half side wheels.

5. The tracked robot according to claim 2, characterized in that the tensioning wheel and the plurality of load bearing wheels are respectively composed of two half side wheels.

6. The tracked robot according to claim 1, characterized by further comprising a buffering mechanism arranged at the tensioning wheel and used for providing a certain buffering space for the track at the tensioning wheel.

7. The tracked robot according to claim 6, characterized in that the buffering mechanism comprises a shock absorber and a tensioning wheel carrier, wherein the tensioning wheel carrier is fixed on the load bearing wheel axles, and the shock absorber is fixed between the tensioning wheel axle and the tensioning wheel carrier.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] FIG. 1 is an overall structural view of a tracked robot of the present invention;

[0013] FIG. 2 is a partial structural view of a tracked robot of the present invention;

[0014] FIG. 3 is a structural view of a track of the present invention; and

[0015] FIG. 4 is a partial structural view of a tracked robot of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0016] A more detailed description of the above and other technical characteristics and advantages of the present invention is given as follows in combination with the drawings.

First Embodiment

[0017] FIG. 1 is an overall structural view of a tracked robot of the present invention. As is shown in FIG. 1, a tracked robot comprises a rack 1, two track mechanisms and power components operating respectively in cooperation with the two track mechanisms. Each track mechanism comprises a track 2, a driving wheel 3, a tensioning wheel 4 and a plurality of load bearing wheels 5, wherein the driving wheel 3, the tensioning wheel 4 and the load bearing wheels 5 are sleeved with the track 2, the driving wheel 3, the tensioning wheel 4 and the load bearing wheels 5 are rotatably arranged on the track 1 respectively through a driving wheel axle, a tensioning wheel axle and load bearing wheel axles, the tensioning wheel 4 is used for tensioning the track 2, and the driving wheel 3 drives the tensioning wheel 4 and the load bearing wheels 5 to rotate through the track 2. Baffles are arranged on the outer sides of the driving wheels 3, the tensioning wheels 4 and the multiple load bearing wheels 5, the tracks 2 are embedded between the baffles 6, and thus the baffles 6 can limit the movement spaces of the tracks and prevent the tracks 2 from derailing.

[0018] FIG. 2 is a partial structural view of the tracked robot of the present invention. FIG. 3 is a structural view of a track of the present invention. As is shown in FIG. 2 and FIG. 3, the driving wheels 3 are provided with clamping grooves 31, and the clamping grooves 31 are matched with shifting teeth 21 inside the tracks 2 to drive the tracks 2 to achieve transmission. The load bearing wheels 5 on one side of each track 2 are provided with clamping grooves 51. The clamping grooves 51 are matched with the shifting teeth 21 inside the tracks to achieve transmission. Other multiple load bearing wheels 5 are respectively composed of two half side wheels. The baffles on the outer sides of the driving wheels 3, the tensioning wheels 4 and the load bearing wheels 5 can limit the movement of the tracks. In this embodiment, the grooves 51 are formed in the load bearing wheels 5 on one sides of the tracks 2 and matched with the shifting teeth 21 inside the tracks to achieve transmission, so that the load bearing wheels 5 are prevented from slipping on the tracks.

[0019] The power components are motors or hydraulic cylinders and are fixedly arranged on the rack 1. The motors or the hydraulic cylinders are connected with the driving wheels 3 through output shafts of the motors or the hydraulic cylinders so as to provide power for the driving wheels 3. In this embodiment, the power components are motors and preferably servo motors, and batteries or other power supplies are adopted to supply power to the power components. In this embodiment, the two servo motors act on the driving wheels 3 in the two track structures respectively. Each servo motor can receive signals independently, and thus the robot can be controlled to advance, retreat or steer by controlling the servo motors to rotate forwards or reversely and controlling the rotating speed difference between the servo motors.

Second Embodiment

[0020] As for the aforesaid tracked robot, the second embodiment is different from the above embodiment in that the driving wheels 3 are provided with clamping grooves 31 matched with shifting teeth 21 inside the tracks 2 to drive the tracks 2 to achieve transmission, the load bearing wheels 5 on both sides of each track 2 are provided with grooves 51 (grooves in the load bearing wheel 5 on one side are not shown in the figures), the grooves 51 are matched with the shifting teeth 21 inside the tracks to achieve transmission, each tensioning wheel 3 and each of other multiple load bearing wheels 5 are respectively composed of two half side wheels, and baffles on the outer sides of the driving wheels 3, the tensioning wheels 4 and the load bearing wheels 5 can limit the movement of the tracks.

[0021] In this embodiment, the bearing wheels 5 on both sides of each track 2 are provided with the corresponding grooves 51, and the grooves 51 are matched with the shifting teeth 21 inside the tracks to achieve transmission, so that the load bearing wheels 5 are prevented from slipping on the tracks.

Third Embodiment

[0022] As for the aforesaid tracked robot, the third embodiment is different from the above embodiments in that the driving wheels 3 are provided with clamping grooves 31 matched with shifting teeth 21 inside the tracks 2 to drive the tracks 2 to achieve transmission, each tensioning wheel 4 and each load bearing wheel 5 are respectively composed of two half side wheels (each load bearing wheel is composed of two half side wheels not shown in the figures), and baffles 6 on the outer sides of the driving wheels 3, the tensioning wheels 4 and the load bearing wheels 5 can limit the movement of the tracks.

Fourth Embodiment

[0023] As for the aforesaid tracked robot, the fourth embodiment is different from the above embodiments in that as is shown in FIG. 4 which is a partial structural view of the tracked robot of the present invention, the tracked robot further comprises a buffering mechanism arranged on each tensioning wheel 4 and used for providing a certain buffering space for the track 2 corresponding to the tensioning wheel 4.

[0024] Each buffering mechanism comprises a shock absorber 71 and a tensioning wheel carrier 72, wherein the tensioning wheel carrier 72 is fixed to the corresponding load bearing wheel axles, and the shock absorber 71 is fixed between the corresponding tensioning wheel axle and the tensioning wheel carrier 72. When the tracked robot vibrates in the operating process, the buffering mechanisms can achieve a buffering effect.

Fifth Embodiment

[0025] As for the aforesaid tracked robot, the fifth embodiment is different from the above embodiments in that as is shown in FIG. 3, each track 2 is composed of a plurality of convex platforms 22. The convex platforms 22 make direct contact with a wall surface to improve the friction force.

[0026] Attractive components 23 are arranged in gaps between the convex platforms 22. When the robot climbs on the wall surface, the attractive components 23 can provide sufficient attraction pressure for the robot and also can reduce the collision between the robot and the wall surface, thereby making the robot walk more smoothly. Wherein, the attractive components are permanent magnets, electromagnetic suction cups or negative-pressure suction cups. In this embodiment, the attractive components 23 are preferably slightly lower than the convex platforms 22.

[0027] Furthermore, the surfaces of the convex platforms 22 are provided with patterns. Thus, when the convex platforms 22 are attached to the wall surface, the patterns on the surfaces of the convex platforms 22 can further increase the friction coefficient between the tracks 2 and the wall surface, thereby improving the friction force.

[0028] The embodiments mentioned above are only preferred embodiments of the present invention.

[0029] What should be pointed out is that for those ordinarily skilled in the field, various improvements and supplements can be made without deviating from the method of the present invention, and all these improvements and supplements also should fall within the protection scope of the present invention.