A pneumatic automotive height adjuster assembly provides at least one bag removably connected to a vehicle having a frame. The at least one bag is configured to adjust a height of the frame. An air supply line has a supply end and a discharge end. The discharge end is in fluid communication with each of the at least one bag. The air supply is configured to provide air to inflate the at least one bag. A switch is in fluid communication with the supply end of the air supply line. The switch has a first discharge, a second discharge, and a switch input. A leveling valve is in fluid communication with the first discharge. The air supply line is in fluid communication with the second discharge. An air supply is in fluid communication with the leveling valve and the switch input.

A utility vehicle includes a plurality of ground-engaging members, a frame, a powertrain assembly, a front suspension assembly, and a rear suspension assembly. A cargo bed may be supported by the frame at the rear of the vehicle. The vehicle also includes an operator seat and at least one passenger seat positioned within an operator area. In one embodiment, the vehicle includes doors to enclose the operator area.

A utility vehicle includes a plurality of ground-engaging members, a frame, a powertrain assembly, a front suspension assembly, and a rear suspension assembly. A cargo bed may be supported by the frame at the rear of the vehicle. The vehicle also includes an operator seat and at least one passenger seat positioned within an operator area. In one embodiment, the vehicle includes doors to enclose the operator area.

A vehicle suspension system may include a first suspension assembly operably coupling a first wheel to a chassis of a vehicle, a second suspension assembly operably coupling a second wheel to the chassis where the first and second wheels form a pair of front wheels, a third suspension assembly operably coupling a third wheel to the chassis, a fourth suspension assembly operably coupling a fourth wheel to the chassis where the third and fourth wheels forming a first pair of rear wheels, and a payload extension kit that is attachable to the chassis non-permanently. The payload extension kit may include a fifth suspension assembly operably coupling a fifth wheel to a sub-frame extension of the payload extension kit, and a sixth suspension assembly operably coupling a sixth wheel to the sub-frame extension, where the fifth and sixth wheels form a second pair of rear wheels.

Methods and systems are described that use multiple node-enabled autonomous transport vehicles on a single logistics operation having multiple legs performed by different transport vehicles with enhanced transfer of the item being shipped between such vehicles. A first or primary master node on a first node-enabled autonomous transport vehicle detects a signal from the second master node on a second transport vehicle, navigates to the second transport vehicle based on the detected signal and its direction, and may dock in a transfer configuration. At least one item (or a container with an item) is transferred as payload from the first to the second vehicle using one or more object manipulation systems on respective ones of the first and second transport vehicles. The second vehicle then detects a signal from another node, and navigates to that node as another leg in the multi-leg operation.

Methods are described that perform dispatched store-to-consumer logistics operations for an ordered item using a modular autonomous bot apparatus assembly and a dispatch server. A dispatch command is received from the dispatch server. The different modular components of the bot assembly are verified to be compatible with the dispatched operation and the ordered item is received in a payload area of a modular cargo storage system. The bot assembly autonomously moves from an origin location to a destination location and notifies the delivery recipient of the approach delivery. When delivery recipient authentication input is received that correlates to the authentication information, selective access is provided to the ordered item within the cargo storage system at the destination location. The bot apparatus monitors unloading, and autonomously moves back to the origin location after the ordered item is detected as removed from the cargo storage system.

Methods and systems are provided for adjusting a height of an electric vehicle with an adjustable suspension system. In one example, a method comprises: during a vehicle stop event, adjusting a height of a skateboard frame of an electric vehicle via an adjustable suspension system, based on at least one sensor input indicative of a desired skateboard frame height. In this way, user activities, including loading and unloading, may be facilitated.

A modular multiple mobility base assembly apparatus is described for transporting an item being shipped having a base adapter plate and two cooperating and coordinating modular mobility bases that are each coupled to the bottom of the base adapter plate and collectively support the base adapter plate. One of the modular mobility bases operations a master autonomous mobile vehicle, while the other operates as a slave autonomous mobile vehicle that receives propulsion and steering control signals from the master while providing feedback sensor data to the master for use in coordinated and cooperative movement of the assembly apparatus. Each of the modular mobility bases also including respective wireless transceivers through which at least the control signals and sensor data are provided between mobility base units.

Methods are described that perform a dispatched inventory operation related to an inventory item within a modular autonomous bot apparatus assembly and a dispatch server. modular mobile autonomy control module (MAM) receives an inventory dispatch command from the dispatch server and a modular cargo storage system (CSS) receives the inventory item at an inventory hub location. The MAM autonomously causes the assembly to then move to a remote business facility as a destination location, receive authentication input from an authorized delivery recipient, coordinates with the CSS to provide selective access to the inventory item, detects when the inventory item has been removed from within the CSS, and autonomously causes the assembly to move on a return route back to the inventory hub location after removal of the inventory item.

Methods are described that perform dispatched store-to-consumer logistics operations for an ordered item using a modular autonomous bot apparatus assembly and a dispatch server. A dispatch command is received from the dispatch server. The different modular components of the bot assembly are verified to be compatible with the dispatched operation and the ordered item is received in a payload area of a modular cargo storage system. The bot assembly autonomously moves from an origin location to a destination location and notifies the delivery recipient of the approach delivery. When delivery recipient authentication input is received that correlates to the authentication information, selective access is provided to the ordered item within the cargo storage system at the destination location. The bot apparatus monitors unloading, and autonomously moves back to the origin location after the ordered item is detected as removed from the cargo storage system.