A robot has an electronic surveillance system embedded within a chassis disposed between two wheels. The wheels include a main body and a plurality of treads. The treads are generally disposed radially around the main body and extend distally from outer portion of the main body. The main body generally defines a plurality of compression cells and may present a substantially frustoconical outer surface.

A robot has an electronic surveillance system embedded within a chassis disposed between two wheels. The wheels include a main body and a plurality of treads. The treads are generally disposed radially around the main body and extend distally from outer portion of the main body. The main body generally defines a plurality of compression cells and may present a substantially frustoconical outer surface.

A robot system includes: an upper body section including one or more end-effectors; a lower body section including one or more legs; and an intermediate body section coupling the upper and lower body sections. An upper body control system operates at least one of the end-effectors. The intermediate body section experiences a first intermediate body linear force and/or moment based on an end-effector force acting on the at least one end-effector. A lower body control system operates the one or more legs. The one or more legs experience respective surface reaction forces. The intermediate body section experiences a second intermediate body linear force and/or moment based on the surface reaction forces. The lower body control system operates the one or more legs so that the second intermediate body linear force balances the first intermediate linear force and the second intermediate body moment balances the first intermediate body moment.

A robot system includes: an upper body section including one or more end-effectors; a lower body section including one or more legs; and an intermediate body section coupling the upper and lower body sections. An upper body control system operates at least one of the end-effectors. The intermediate body section experiences a first intermediate body linear force and/or moment based on an end-effector force acting on the at least one end-effector. A lower body control system operates the one or more legs. The one or more legs experience respective surface reaction forces. The intermediate body section experiences a second intermediate body linear force and/or moment based on the surface reaction forces. The lower body control system operates the one or more legs so that the second intermediate body linear force balances the first intermediate linear force and the second intermediate body moment balances the first intermediate body moment.

A lifting device (10) for moving a motor vehicle, comprising a support structure (100, 100a) suitable to be removably or firmly connected to a vehicle underbody of the motor vehicle, and at least one drive shaft (220) which is rotatably mounted on the support structure (100, 100a). The at least one drive shaft (220) is part of a rotary blade drive (200), which rotary blade drive (200) additionally comprises at least one drive motor (211) for rotating the drive shaft (220) about the axis of rotation (221) thereof, and at least one rotary blade (240), that is connected to the drive shaft (220) so as to be able to rotate about the axis of rotation (221) such that the rotary blade (240) can be supported on the ground and the motor vehicle can be lifted and/or moved as a result of the torque (M) acting along the drive shaft (220).

A lifting device (10) for moving a motor vehicle, comprising a support structure (100, 100a) suitable to be removably or firmly connected to a vehicle underbody of the motor vehicle, and at least one drive shaft (220) which is rotatably mounted on the support structure (100, 100a). The at least one drive shaft (220) is part of a rotary blade drive (200), which rotary blade drive (200) additionally comprises at least one drive motor (211) for rotating the drive shaft (220) about the axis of rotation (221) thereof, and at least one rotary blade (240), that is connected to the drive shaft (220) so as to be able to rotate about the axis of rotation (221) such that the rotary blade (240) can be supported on the ground and the motor vehicle can be lifted and/or moved as a result of the torque (M) acting along the drive shaft (220).

Provided is a pipe interior inspection robot that has characteristics of having an extremely simple device structure to easily achieve dustproof and waterproof properties, being able to pass through a pipe bent in any direction, and enabling the selection of the advancing direction.

A pipe interior inspection robot for inspecting the inside of a pipe branched from a pipe header, the robot including: 1) a moving means having a structure capable of being introduced from a pipe base, which is an inlet of the pipe header, and capable of moving in the pipe header and being fixed to a pipe wall inside the pipe header at a desired position; 2) a mechanism for specifying a position of a pipe to be inspected; and 3) a mechanism for inspecting a condition inside the pipe to be inspected.

Provided is a pipe interior inspection robot that has characteristics of having an extremely simple device structure to easily achieve dustproof and waterproof properties, being able to pass through a pipe bent in any direction, and enabling the selection of the advancing direction.

A pipe interior inspection robot for inspecting the inside of a pipe branched from a pipe header, the robot including: 1) a moving means having a structure capable of being introduced from a pipe base, which is an inlet of the pipe header, and capable of moving in the pipe header and being fixed to a pipe wall inside the pipe header at a desired position; 2) a mechanism for specifying a position of a pipe to be inspected; and 3) a mechanism for inspecting a condition inside the pipe to be inspected.

A system includes an inspection robot having an input sensor comprising a laser profiler and a plurality of wheels structured to engage a curved portion of an inspection surface, wherein the laser profiler is configured to provide laser profiler data of the inspection surface; a controller, comprising: a profiler data circuit structured to interpret the laser profiler data; determine a feature of interest is present at a location of the inspection surface in response to the laser profiler data; and wherein the feature of interest comprises a shape description of the inspection surface at the location of the feature of interest.

A system includes an inspection robot having an input sensor comprising a laser profiler and a plurality of wheels structured to engage a curved portion of an inspection surface, wherein the laser profiler is configured to provide laser profiler data of the inspection surface; a controller, comprising: a profiler data circuit structured to interpret the laser profiler data; determine a feature of interest is present at a location of the inspection surface in response to the laser profiler data; and wherein the feature of interest comprises a shape description of the inspection surface at the location of the feature of interest.