A vacuum suction wall-climbing robot including a body, a vacuum pump and at least four leg mechanisms is disclosed. Each leg mechanism includes a foot unit and a limb unit connecting the foot unit and the body. The foot unit includes a plurality of suction sets connected to the vacuum pump through a pipe. Each suction set includes a sucker able to create a vacuum state within a contact area through the operation of the vacuum pump, and a sheet valve arranged between the pipe and the sucker, which automatically closes the connection between the pipe and the sucker when the vacuum state between the sucker and the contact area becomes a non-vacuum state.

A vacuum suction wall-climbing robot including a body, a vacuum pump and at least four leg mechanisms is disclosed. Each leg mechanism includes a foot unit and a limb unit connecting the foot unit and the body. The foot unit includes a plurality of suction sets connected to the vacuum pump through a pipe. Each suction set includes a sucker able to create a vacuum state within a contact area through the operation of the vacuum pump, and a sheet valve arranged between the pipe and the sucker, which automatically closes the connection between the pipe and the sucker when the vacuum state between the sucker and the contact area becomes a non-vacuum state.

The present disclosure provides a stair climbing gait planning method and an apparatus and a robot using the same. The method includes: obtaining first visual measurement data through a visual sensor of the robot; converting the first visual measurement data to second visual measurement data; and performing a staged gait planning on a process of the robot to climb the staircase based on the second visual measurement data. Through the method, the visual measurement data is used as a reference to perform the staged gait planning on the process of the robot to climb the staircase, which greatly improves the adaptability of the robot in the complex scene of stair climbing.

A robot device comprising a main body portion and two elongated legs, wherein: a) each of said legs is connected to said main body portion by a four-bar extension mechanism; and b) each one of said legs is rotatable around a corresponding axis positioned along the distal-proximal direction.

A robot device comprising a main body portion and two elongated legs, wherein: a) each of said legs is connected to said main body portion by a four-bar extension mechanism; and b) each one of said legs is rotatable around a corresponding axis positioned along the distal-proximal direction.

A method for negotiating stairs includes receiving image data about a robot maneuvering in an environment with stairs. Here, the robot includes two or more legs. Prior to the robot traversing the stairs, for each stair, the method further includes determining a corresponding step region based on the received image data. The step region identifies a safe placement area on a corresponding stair for a distal end of a corresponding swing leg of the robot. Also prior to the robot traversing the stairs, the method includes shifting a weight distribution of the robot towards a front portion of the robot. When the robot traverses the stairs, the method further includes, for each stair, moving the distal end of the corresponding swing leg of the robot to a target step location where the target step location is within the corresponding step region of the stair.

A method for negotiating stairs includes receiving image data about a robot maneuvering in an environment with stairs. Here, the robot includes two or more legs. Prior to the robot traversing the stairs, for each stair, the method further includes determining a corresponding step region based on the received image data. The step region identifies a safe placement area on a corresponding stair for a distal end of a corresponding swing leg of the robot. Also prior to the robot traversing the stairs, the method includes shifting a weight distribution of the robot towards a front portion of the robot. When the robot traverses the stairs, the method further includes, for each stair, moving the distal end of the corresponding swing leg of the robot to a target step location where the target step location is within the corresponding step region of the stair.

A walking vehicle including a chassis and a plurality of wheel-leg components is described. The plurality of wheel-leg components are collectively operable to provide wheeled locomotion and walking locomotion.

A walking vehicle including a chassis and a plurality of wheel-leg components is described. The plurality of wheel-leg components are collectively operable to provide wheeled locomotion and walking locomotion.

A surveillance robot is adapted with a light-weight body formed with light-weight foam, wheel motors arranged within the light-weight foam and connected to wheels extending out from the body and drivable by the wheel motors, a sensor system at least partially arranged within the light-weight foam for picking up any of image, audio and environmental data, an electronic controller arranged within the light-weight foam, connected to the sensor system and wheel motors, and including a memory and a set of computer instructions that provide for surveillance robot operation, and a transceiver section connected to the electronic controller and including an antenna for transmitting and receiving commands, the image data, the audio data and/or the environmental data to or from the electronic controller. The light-weight foam substantially surrounds, supports and protects the wheel motors, sensor system, electronic controller and transceiver from mechanical shock as the robot traverses obstacles.