A system for transporting products throughout a manufacturing environment, includes a mobile robot including a frame, a tractive element coupled to the frame, a motor coupled to the frame and configured to drive the tractive element to propel the vehicle, at least one sensor configured to collect sensor data regarding a surrounding environment of the vehicle, an interface configured to engage a product, a lift assembly coupling the interface to the frame and configured to raise the interface relative to the frame, and a controller operatively coupled to the motor, the at least one sensor, and the lift assembly. The controller is configured to control the motor and the lift assembly based on information from the at least one sensor to autonomously transport the product.

A vehicle includes a frame, a drivetrain coupled to the frame, a base assembly coupled to the frame, and a lifting implement coupled to and supported on the base assembly. The lifting implement includes a platform, a cradle rotatably coupled to and supported on the platform so that the cradle, a scissor assembly coupled between the platform and the base assembly, and a lift actuator coupled between the base assembly and the scissor assembly. The lift actuator is configured to selectively raise the cradle relative to the base assembly. The lift actuator is a multi-stage telescoping actuator that includes a base stage, an intermediate stage, and an outer stage. The base stage is coupled to the base assembly, the outer stage is coupled to the scissor assembly, and the intermediate stage is arranged between the base stage and the outer stage.

A vehicle system includes a vehicle, one or more input devices, and one or more memory devices storing instructions thereon. When executed by one or more processors, the instructions cause the one or more processors to retrieve, from the one or more memory devices, a floorplan of a production system, receive a current position of the vehicle, and receive, from the one or more input devices, one or more inputs. The one or more inputs include one or more of one or more locations in the production system, a footprint of the vehicle, or one or more obstacles. The instructions also cause the one or more processors to generate a route for the vehicle from the current position of the vehicle to the one or more locations based on the one or more inputs.

An autonomous vehicle system includes a vehicle and a sensor movably coupled with the vehicle. An actuator is configured to move the sensor to reposition the sensor on the vehicle. A controller is configured to detect an obstruction of the sensor and operate the actuator to reposition the sensor.

A vehicle may include a frame, a drive system coupled to the frame to propel and steer the vehicle, an energy storage device configured to provide power to the drive system, and a lift implement coupled to the frame, the lift implement comprising a cradle and a lift assembly configured to adjust a position of the cradle relative to the frame. The vehicle may further include at least one of an audio output device or a visual output device and a controller configured to: determine a condition of the vehicle and provide an alert based on the determined condition, wherein the determined condition is at least one of a plurality of conditions, and wherein each condition of the plurality of conditions is associated with a unique alert, the unique alert comprising at least one unique aspect specific to the condition relative to the other conditions of the plurality of conditions.

A vehicle includes a frame, a drive system coupled to the frame to propel and steer the vehicle, an energy storage device coupled to the frame and configured to provide power to the drive system, a lift implement coupled to the frame, the lift implement comprising a cradle to support a load and a lift assembly configured to adjust a position of the cradle relative to the frame, one or more sensors configured to provide sensing data indicative of an environment surrounding the vehicle, and a controller comprising one or more memory devices having instructions stored thereon, that, when executed by one or more processors, cause the one or more processors to: operate the vehicle along a first path, determine the first path extends into a first predefined zone, generate a second path that avoids the first predefined zone; and operate the vehicle along the second path.

An autonomous vehicle system includes a vehicle including a base assembly having a front surface, a rear surface opposite the front surface, and side surfaces extending between the front surface and the rear surface. A sensor system is coupled to the base assembly and configured to detect one or more objects located in an area near the vehicle. The sensor system includes a first sensor oriented parallel with at least one of the front surface, the rear surface, or the side surfaces, and a second sensor oriented non-parallel with the front surface, the rear surface, and the side surfaces. A control system is configured to receive a communication regarding the detection of the one or more objects from the sensor system and generate one or more controls for at least one of the base assembly or one or more tractive elements.

A manufacturing system includes a vehicle configured to facilitate movement of a product throughout a manufacturing environment. The vehicle assembly includes a chassis, an interface coupled to the chassis and configured to support the product, and a sensor coupled to the interface. The sensor is operatively coupled to a controller, which is configured to receive sensor data, receive current stage of assembly of a product, determine an expected force based on the current stage of assembly, and compare the measured force and expected force. In response to a determination that the measured force differs from the expected force, the controller provides a notification to the user of the current status of the product.

A foldable portable barrier includes a base, a barrier arm pivotably coupled to the base for pivoting between a stowed position relative to the base and a deployed position, a first side arm pivotably coupled to the base for pivoting between a stowed position over the barrier arm when stowed and a deployed position, and a second side arm pivotably coupled to the base for pivoting between a stowed position over the first arm when stowed and a deployed position.

A handling truck comprises a mast assembly, a base, a moving assembly, and a connecting member. The base is fixedly disposed at the bottom end of the mast assembly, and the base is provided with a socket portion. The moving assembly includes a leg assembly and a connecting portion, wherein one end of the connecting portion is connected to the leg assembly, and the other end of the connecting portion is configured for socket engagement with the socket portion. The moving assembly is configured to drive the mast assembly to move on a plane. The connecting member is configured to pass through the socket portion and the connecting portion to achieve a detachable connection between the moving assembly and the base. The present application provides a handling truck capable of reducing packaging costs and transportation costs.