Systems, methods and apparatus for rapid development of an inspection scheme for an inspection robot are disclosed. An apparatus may include an inspection definition circuit to interpret an inspection description value, and a robot configuration circuit to determine an inspection robot configuration description in response to the inspection description value. The apparatus may further include a configuration implementation circuit, communicatively coupled to a configuration interface of an inspection robot, to provide at least a portion of the inspection robot configuration description to the configuration interface.

Systems, apparatus and methods for providing an inspection map are disclosed. An apparatus for performing an inspection may include an inspection data circuit to interpret inspection data, a robot positioning circuit to interpret position data, and a processed data circuit to link the inspection data with the position data to determine position-based inspection data. The apparatus may further include a user interaction circuit to interpret an inspection visualization request for an inspection map and an inspection visualization circuit to determine the inspection map based on the position-based inspection data, and a provisioning circuit structured to provide the inspection map to a user device.

Tipping over of a work machine is prevented. The work machine includes: a vehicular body; a rear axle attached to the vehicular body to be capable of undergoing a roll motion with respect to an axis extending in a front-rear direction of the vehicular body; and a controller. The controller acquires stability of the center of gravity of the vehicular body, and controls the roll motion of the rear axle with respect to the vehicular body based on the stability.

Systems and methods for an inspection robot having replaceable sensor sled portions are disclosed. An example system may include: an inspection robot including a plurality of payloads; a plurality of arms, each of the plurality of arms pivotally mounted to one of the plurality of payloads; and a plurality of sleds, each sled mounted to one of the plurality of arms. At least one of the plurality of sleds includes an upper portion coupled to a replaceable lower portion, where the replaceable lower portion includes a portion of a delay line for a sensor of the inspection robot.

A tilting car frame comprising a lower center frame including a horizontal member, a first support member, a second support member, and first and second horizontal link members each having a vertical link. A rotation center axis support extends from a center of the horizontal member. A first variable length lever link is slidably connected to the first support member and is facing the rotation center axis support, and a second variable length lever link is slidably connected to an end of the second support member that is facing the rotation center axis support. A rotating member having first and second extension members is rotatably connected to the rotation center axis support, wherein the first extension member is hinged to an end of a first variable length link member, and the second extension member is hinged to an end of a second variable length link member.

An inspection robot includes a robot body, at least two sensors, a drive module, a stability assist device and an actuator. The at least two sensors are positioned to interrogate an inspection surface and are communicatively coupled to the robot body. The drive module includes at least two wheels that engage the inspection surface. The drive module is coupled to the robot body. The stability assist device is coupled to at least one of the robot body or the drive module. The actuator is coupled to the stability assist device at a first end, and coupled to one of the drive module or the robot body at a second end. The actuator is structured to selectively move the stability assist device between a first position and a second position. The first position includes a stored position. The second position includes a deployed position.

A system includes an inspection robot having a plurality of acoustic sensors coupleable to an inspection surface through a couplant chamber defining a delay line therebetween; the plurality of acoustic sensors configured to provide raw acoustic data; a controller, comprising: an acoustic data circuit structured to interpret the raw acoustic data; a thickness processing circuit structured to determine a primary mode value and a primary mode score value in response to the raw acoustic data; and wherein the thickness processing circuit is further structured to determine a thickness value in response to the primary mode value and the primary mode score value.

A system includes an inspection robot comprising a lead inspection sensor providing lead inspection data, and a trailing inspection sensor; a controller, comprising: an inspection data circuit structured to interpret the lead inspection data; a sensor configuration circuit structured to determine a trailing sensor configuration change for the trailing inspection sensor in response to the lead inspection data; and a sensor operation circuit structured to adjust a trailing sensor configuration for the trailing inspection sensor in response to the trailing sensor configuration change.

Controllers for inspection robots traversing an obstacle are described. In an embodiment a controller may include an obstacle sensory data circuit to interpret obstacle sensory data provided by an obstacle sensor of an inspection robot, an obstacle processing circuit to determine refined obstacle data, and an obstacle notification circuit to generate and provide obstacle notification data to a user interface device. The controller may further include a user interface circuit to interpret a user request value from the user interface device, and to determine an obstacle response command value in response to the user request value; and an obstacle configuration circuit to provide the obstacle response command value to the inspection robot during the interrogating of the inspection surface.

A system includes an inspection robot having a plurality of input sensors, the plurality of input sensors distributed horizontally relative to an inspection surface and configured to provide inspection data of the inspection surface at selected horizontal positions; a controller, comprising: a position definition circuit structured to determine an inspection robot position of the inspection robot on the inspection surface; a data positioning circuit structured to interpret the inspection data, and to correlate the inspection data to the inspection robot position on the inspection surface; and wherein the data positioning circuit is further structured to determine position informed inspection data in response to the correlating of the inspection data with the inspection robot position.