A outdoor robot includes an execution apparatus and an execution motor for driving the execution apparatus to perform a work task. The control method includes: obtaining a load parameter of the execution motor during running of the outdoor robot; calculating a change rate parameter of a load; and when it is determined that the change rate parameter of the load represents that the load increases and the change rate parameter of the load exceeds a preset threshold range, braking running of the execution apparatus.

Provided herein is a system and method for regulating a sensor enclosure of a vehicle. The system comprises an enclosure comprising a vent at a base of the enclosure, one or more sensors configured to determine a parameter of the vehicle or the enclosure, a fan configured to regulate an internal temperature of the enclosure, and a controller configured to regulate a rotation speed of the fan based on the parameter of the vehicle or the enclosure. The regulating system further comprises a deflector connected to the enclosure and configured to direct an airflow into the vent based on the parameter.

A robot detects, through a sensor, the location and movement direction of a user and an object near the user, sets a nearby ground area in front at the feet of the user according to the detected location and movement direction of the user, controls an illumination device in the robot to irradiate the nearby ground area with light while driving at least one pair of legs or wheels of the robot to cause the robot to accompany the user, specifies the type and the location of the detected object, and if the object is a dangerous object and is located ahead of the user, controls the illumination device to irradiate a danger area including at least a portion of the dangerous object with light in addition to irradiating the nearby ground area with light.

The present application belongs to the technical field of smart appliances, and relates to a delivery control method, which comprises the steps of: transferring goods to a delivery device according to the number of personnel; and controlling the delivery device to move to a set target position. By adopting the method, the corresponding quantity of goods can be configured based on the number of personnel, and moved to the target position by the delivery device, so that the required quantity of goods can be distributed to the target position without requiring a user to give control instructions, thereby providing convenience for the user; meanwhile, the required quantity can be distributed at a time, thereby improving the distribution efficiency and improving the user experience. The present application further discloses a delivery control device and a delivery device.

A lift system for an automated storage system of the type where storage containers are stacked in storage columns arranged in a grid, and where automated container handling vehicles retrieve and replace containers from a top level of the grid. The lift system has a platform vertically movable adjacent to a face of the grid, arranged for receiving and transporting one or more containers. A dedicated mechanical device is arranged for grabbing, lifting and moving the storage containers from a staging area at the top of the grid and placing containers on the platform and vice versa.

A monitoring device includes a housing adhered to a drop well of a wheel inside of a vehicle tire. The housing rotates with the wheel. An electrical circuit disposed within the housing. The electrical circuit including a load sensing device disposed within the housing. The load sensing device sensing forces exerted on the wheel. A transceiver coupled to the electrical circuit. The transceiver communicates load data sensed by the load sensing device to components exterior of the wheel.

A vehicle control system is provided to maintain an SOC level of the battery during autonomous operation of the vehicle. The control system is applied to a vehicle that can be operated autonomously by controlling an engine, a motor, a steering system, a brake system etc. autonomously by a controller, and the vehicle is allowed to coast by manipulating a clutch. During autonomous operation of the vehicle, a first coasting mode in which the engine is stopped and the clutch is disengaged is selected if the SOC level is higher than a threshold level, and a second coasting mode in which the engine is activated and the clutch is disengaged is selected if the SOC level is lower than the threshold level.

An example method may include i) determining a first distance between a pair of feet of a robot at a first time, where the pair of feet is in contact with a ground surface; ii) determining a second distance between the pair of feet of the robot at a second time, where the pair of feet remains in contact with the ground surface from the first time to the second time; iii) comparing a difference between the determined first and second distances to a threshold difference; iv) determining that the difference between determined first and second distances exceeds the threshold difference; and v) based on the determination that the difference between the determined first and second distances exceeds the threshold difference, causing the robot to react.

A mobile robot adapted to traverse vertical obstacles. The robot comprises a frame and at least one wheel positioned in a front section of the robot, at least one middle wheel positioned in a middle section of the robot, at least one back wheel positioned in a back section of the robot, and at least one further wheel in the front, middle or back of the robot. The robot also comprises at least one motor-driven device for exerting a downward and/or upward force on the middle wheel and at least two motors for driving the wheels and the motor-driven device. Also disclosed is a method of climbing using a mobile robot as disclosed.

Multiple printer housings and powder bed carts may be coordinated to perform a variety of 3D printing operations. Printer housings may call for powder bed carts directly or through a control station. A requested powder bed cart may be dispatched from a stand-by area and may navigate to the requesting printer housing autonomously using its magnetic guide sensors to follow lines of magnetic tape on the floor. At the requesting printer housing, the powder bed cart may dock, move the powdered media trays and powder bed into position by elevating on its jack screws, and printing operations may commence. As the powder bed cart becomes depleted of powdered media, the powder bed cart may decouple from the printer housing and return to the stand-by area where the trays are refilled with powdered media, and its batteries are recharged.