A service vehicle for charging a parked electric vehicle, the service vehicle including: one or more charging robots disposed on the service vehicle, the one or more charging robots being configured to supply electrical energy to the parked electric vehicle to charge one or more batteries of the electric vehicle. Where the one or more charging robots are configured to have a first shape for storage on the service vehicle and to have a second shape when deployed from the service vehicle, the second shape being configured to charge the one or more batteries of the electric vehicle; and the second shape being different from the first shape. The charging robot including a source of electrical energy; and a charging cable for electrically connecting the source of electrical energy to the one or more batteries of the electric vehicle.

A power transmission device of a work vehicle includes a generator, a motor, and an energy storage unit. The energy storage unit stores electricity generated by the generator. A forward/backward travel switch operation device receives an instruction for forward or backward travel from an operator. A vehicle speed detection unit detects the speed of the vehicle. A control unit includes an energy management requirement determination unit. The energy management requirement determination unit determines, on the basis of the difference between a target electricity storage amount and a current electricity storage amount in the energy storage unit, the energy management required power required by the power transmission device for charging the energy storage unit. The energy management requirement determination unit increases the target electricity storage amount when a first travel direction according to the instruction and a second travel direction determined from the vehicle speed are different.

Disclosed are various techniques to optimize load delivery management of multiple vehicles along route. The optimization can involve evaluating vehicle-in-front information along with look ahead data to determine a recommended speed target and/or idle stop times and durations. The optimization can also involve determining bottleneck conditions from one or more vehicles and/or one or more infrastructure conditions and providing one or more recommended actions in response thereto.

Disclosed are various techniques to optimize load delivery management of multiple vehicles along route. The optimization can involve evaluating vehicle-in-front information along with look ahead data to determine a recommended speed target and/or idle stop times and durations. The optimization can also involve determining bottleneck conditions from one or more vehicles and/or one or more infrastructure conditions and providing one or more recommended actions in response thereto.

In one or more arrangements, a portable livestock enclosure system is provided to facilitate stock cropping of a field. The system includes a mobile enclosure and one or more enclosed grazing areas. The one or more enclosed grazing areas are operably connected to the mobile enclosure. The mobile enclosure also includes a set of lift wheel assemblies configured to move a set of wheels between a retracted position and an extended position. The mobile enclosure and one or more enclosed grazing areas are lifted off of the ground to facilitate movement of the portable livestock enclosure system when set of wheels are moved to the extended position. The mobile enclosure and one or more enclosed grazing areas are placed on or near the ground when the set of wheels are moved to the retracted position.

The invention relates to a battery pack arrangement (40) for a vehicle (10) comprising a battery pack (43, 47, 49) having a first battery module (64) with a first set of battery cells (84), a second battery module (67) with a second set of battery cells (87), and a thermal management member (70) arranged there between, wherein the first battery module and the second battery module are arranged on opposite sides (72, 74) of the thermal management member (70), the thermal management member having a first thermally conductive surface (73) for regulating a temperature of the first battery module and a second thermally conductive surface (75) for regulating a temperature of the second battery module, wherein the battery pack arrangement further comprises a suspension attachment (80) configured to attach the battery pack arrangement in a generally vertical orientation to a vehicle frame (20) of the vehicle.

An air supply device control system may include a sensor configured to detect a trailer to be provided in an eco-friendly commercial vehicle, an air supply device configured to compress and supply air, and a controller electrically connected to the air supply device and configured to control rotation speed of the air supply device to control the air of the air supply device, wherein the controller increases the rotation speed of the air supply device based on whether the trailer is provided in the eco-friendly commercial vehicle, which is detected by the sensor.

An apparatus for transporting a load is described, including: a body including a part or portion for engaging with or connecting to a load to be transported; a ground-engaging device supporting the body, the ground-engaging device for effecting movement of the body over a surface; a transmitter module; a receiver module; and a controller for communicating with the transmitter and receiver modules and the ground engaging device and for receiving status signals from components and/or devices of the apparatus, wherein the controller is capable of conducting a check as to the status of the components and/or devices of the apparatus, and after completing said check to provide an “apparatus operative” or “apparatus non-operative” signal to the transmitter module, wherein the transmitter module is configured to transmit the “apparatus operative” or “apparatus non-operative” signal, and wherein the receiver module is configured to receive from a first predetermined, or designated, other such apparatus its respective “apparatus operative” or “apparatus non-operative” signals.

A robotic shuttle system for logistics and a control method thereof are disclosed. The novel robotic shuttle system for logistics is compact in structure, convenient for disassembly and maintenance, and integrated intelligently, and may precisely realize the functions such as moving, lifting, carrying, fault warning, etc. The novel robotic shuttle system for logistics includes a novel logistics shuttle robot and a WCS automatic storage system; the novel logistics shuttle robot includes a vehicle body, a straight motor, a straight wheel, a transverse motor, a transverse wheel, a position sensor, a lifting motor, an encoder, a PLC controller, a lifting position sensor, a telescopic fork, a finger, a telescopic fork position sensor, a telescopic fork motor, and an antenna; and the bottom of the vehicle body is respectively provided with the straight wheel and the transverse wheel.

A modular robot system which may be configured to accommodate packages of varying sizes is provided. The modular robot may include a base have omni-directional wheels and cameras and sensors, one or more modular containers, and a lid, which may be releasably linked together to form a small, medium or larger units. The base, one or more modular containers, and the lid may be electrically linked to provide information to be used in a number of ways. For example, the electrical link may allow two or more modular robots to communicate with each other, enable external displays of multiple modules to act as one large unit, control the motion of the drawers, e.g., allowing them to open/close, and allow the processor(s) in the lid to communicate with the drive system of the omni-directional wheels. A set of alternating interlocking rails and tracks on corresponding surfaces enable the various layers of the modular robot to interlock with one another. Interlocking of multiple modular containers may be established by sliding one surface over the other. These sections may be used to create modular robots of varying sizes.