The invention provides a robotic obstacle-crossing device, which mainly comprises a wheel body and an obstacle-crossing body, wherein the wheel body includes a wheel part, a first obstacle-crossing part and a second obstacle-crossing part. When the sweeping robot tilts, the plurality of first recessed portions and the plurality of second recessed portions provided on the periphery of the first obstacle-crossing part and the second obstacle-crossing part provide a climbing function. In addition, when the sweeping robot encounters obstacles or steps, the obstacle-crossing body can provide robot the function of the obstacle-crossing or climbing, thereby reducing the number of situations when the sweeping robot may be trapped or unable to effectively climb upon encountering an obstacle or a steep road surface.

A method of maneuvering a robot includes driving the robot across a surface and turning the robot by shifting a center of mass of the robot toward a turn direction, thereby leaning the robot into the turning direction. The robot includes an inverted pendulum body, a counter-balance body disposed on the inverted pendulum body and configured to move relative to the inverted pendulum body, at least one leg prismatically coupled to the inverted pendulum body, and a drive wheel rotatably coupled to the at least one leg. The inverted pendulum body has first and second end portions and defines a forward drive direction. The method also includes turning the robot by at least one of moving the counter-balance body relative to the inverted pendulum body or altering a height of the at least one leg with respect to the surface.

A walking mechanism for driving a machine body includes a walking wheel group having a plurality of walking wheels attached to the machine body, with two front and two rear wheels relative to a traveling direction. The machine body has two sides with a pair of one of the front wheels and a one of the rear wheels being respectively located on each of the sides and driven to rotate synchronously. Each walking wheel includes an auto tire casing with a tread outer side having a tread pattern distributed along a circumferential direction of the auto tire casing. The tread pattern is configured as a plurality of tread ribs with a respective tread groove formed between each adjacent pair of the tread ribs, the tread pattern radiating outward from an axial center of the walking wheel. A related robot and self-walking mower are also disclosed.

This disclosure relates to a walking mechanism comprising a walking unit and a control unit, wherein the walking unit comprises a load frame, a mandrel is fixedly arranged on the load frame in a penetrating manner, an inner shaft sleeve sleeves the mandrel, and the inner shaft sleeve can rotate around the mandrel; at least two walking and supporting components are arranged on two sides of the load frame respectively; each walking and supporting component comprises a big gear wheel, an outer shaft sleeve and a supporting seat shaft sleeve; each big gear wheel fixedly sleeves the inner shaft sleeve, and a plurality of lock pin holes are formed in each big gear wheel; each outer shaft sleeve and the corresponding big gear wheel are arranged side by side, and each outer shaft sleeve movably sleeves the inner shaft sleeve.

A giant six-legged polar research vehicle with tracked feet, including a platform, six legs arranged at six ends of the platform and six tracked feet arranged below the six legs. A monitoring device is arranged on a top cover. Six power compartments each having a steering device are arranged at six ends of a chassis in the platform. Each leg includes a main traveling device with an upper end and a lower end respectively connected to the steering device and a tracked foot, an auxiliary traveling device with an upper end and a lower end respectively connected to the chassis and the main traveling device, and a connecting device arranged on the main traveling device. The tracked foot includes a main flipping mechanism, an auxiliary flipping mechanism, a tracked foot slewing device, a crawler, a sliding plate and a suspension.

A portable master control unit for a load transporting system configured to be removed from the load to eliminate damage to the control unit and cables when the load is in position.

A load transporting system comprising a plurality of walking systems in the load substructure comprises transverse step window configured such that during a non-longitudinal step at least a portion of the walking system passes into the window. A portable master control unit for a load transporting system configured to be removed from the load to eliminate damage to the control unit and cables when the load is in position.

A two wheeled throwable robot comprises an elongate chassis with two ends, a motor at each end, drive wheels connected to the motors, and a tail extending from the elongate chassis. A rear portion having a deep recess securing the pair of motors with brackets, and batteries with brackets. The forward part having a shallow recess with a printed circuit board secured therein having control circuitry. The wheels are less than six inches in diameter and the robot weighs less than five pounds.

A robotic platform may include a chassis, left and right wheel assemblies, and a controller. The left and right wheel assemblies may include a caster wheel, a motor, a shaft, and a bevel gear. The wheel may be mounted to an axle for rotation about a drive axis and steering about a steering axis. The drive shaft may have one end coupled to the axle and another end wrapped by a respective belt to control rotation of the shaft about the steering axis. The bevel gear may couple the shaft to the axle so rotation of the shaft about the steering axis controls rotation of the wheel about the drive axis to drive the platform in a substantially horizontal direction. The controller may control the left and right drive motors independently, to provide differential drive. Various other assemblies, robots, and methods are also disclosed.

Systems and methods for moving at least one load transporting apparatus may include the load transporting apparatus(es) configured to move in at least one direction, at least one feedback sensing device disposed on and/or within the load transporting apparatus where the sensing device obtains movement measurements of the load transporting apparatus, a first location to receive a pre-determined input, a second location to receive the movement measurement(s), and a processing circuit to compare the movement measurement(s) to the pre-determined input. In a non-limiting embodiment, a pre-loading system may prepare the load transporting apparatus for movement prior to moving or lifting a load by depressing at least one component of the load transporting apparatus.