Inspection robots with a multi-function piston connecting a drive module to a central chassis and systems thereof are disclosed. An example inspection robot may include a center chassis coupled to a payload coupled to at least two inspection sensors. The inspection robot may further include a drive module coupled to the center chassis, the drive module having a drive wheel to engage an inspection surface and a drive piston mechanically interposed between the center chassis and the drive module. The example may further include wherein the drive piston in a first position couples the drive module to the center chassis at a minimum distance between and the drive piston in a second position couples the drive module to the center chassis at a maximum distance between. The example may further include wherein the drive module is independently rotatable relative to the center chassis.

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.

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.

An end effector for engaging flexible packaging materials includes a frame, along with a first and second wheel mounted for rotation with respect to the frame. The first wheel and the second wheel are mounted to the frame relative to each other so that the outer surfaces of the two wheels are positioned opposite of each other. The first wheel and the second wheel can be driven in opposing directions to effectively define a roller intake which can be used to draw the flexible packaging materials of a target parcel between the first wheel and the second wheel. The end effector of the present invention can be combined with a robot to provide an improved system for engaging the flexible packaging materials of a parcel.

A parallel link robot includes a movable portion, a base, a plurality of drive sources, a plurality of links, and a tension member. The plurality of drive sources is attached to the base. The plurality of links is respectively connected to the plurality of drive sources. The tension member is connected between the movable portion and at least one of the plurality of links such that a bending tension is generated.

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.

A system includes an inspection robot having a number of payloads, a number of arms mounted to the payloads, and a number of sleds mounted to the arms, where the sleds comprise an upper portion coupled to a replaceable lower portion, the replaceable lower portion having a bottom surface shaped to accommodate an inspection surface; and an inspection sensor coupled to the upper portion of the one of the plurality of sleds such that the sensor is operationally couplable to the inspection surface.

An example device includes an inner element, an outer surrounding element, and a plurality of connecting flexural elements coupled between the inner element and the outer surrounding element. The inner element has a plurality of reflective surface areas that are configured to reflect light to a sensor. The outer surrounding element surrounds the inner element. The plurality of connecting flexural elements allow the inner element to move relative to the outer surrounding element.

A bionic pneumatic soft gripping device includes a flexible sleeve, a connecting base, a pneumatic artificial muscle, a flexible holder, and a gap tube. The flexible sleeve is an annular jacket-like structure. The flexible holder is a tubular hollow structure having openings at both ends thereof. The pneumatic artificial muscle is wound on the flexible holder. The flexible sleeve is sleeved on the flexible holder connected with the pneumatic artificial muscle through the opening of the flexible sleeve. The pneumatic artificial muscle is connected to a tube joint via a fastening sleeve, and the tube joint is connected to the gap tube. The bionic pneumatic flexible gripping device of the present disclosure has advantages of large gripping force and compliancy, thereby effectively gripping objects in various shapes within its gripping size range.

A system includes an inspection robot having a number of payloads, a number of arms mounted to the payloads, and a number of sleds mounted to the arms. The system includes a number of sensors, each mounted to a corresponding sled, such that the sensor is operationally coupleable to an inspection surface in contact with a bottom surface of the corresponding sled. A couplant chamber is provided within at least two of the sleds, the couplant chamber between a transducer of a sensor and the inspection surface. The system includes a biasing member for each of the arms, where the biasing member provides a down force on the corresponding sled.