A refuse vehicle includes a vehicle chassis and an all-electric vehicle body on the chassis. The body includes a hopper, a refuse storage container, and a plurality of electrically powered body systems. The body systems include an electrically actuated tailgate, an electrically actuated refuse loading assembly, and an electrically actuated refuse packing assembly configured to remove refuse from the hopper and to pack said refuse in the storage container. The vehicle (e.g., vehicle body) further includes a power management module configured to regulate energy usage of the body systems and/or to record and track electrical energy usage in the body systems.

A refuse vehicle includes a vehicle chassis and an all-electric vehicle body on the chassis. The body includes a hopper, a refuse storage container, and a plurality of electrically powered body systems. The body systems include an electrically actuated tailgate, an electrically actuated refuse loading assembly, and an electrically actuated refuse packing assembly configured to remove refuse from the hopper and to pack said refuse in the storage container. The vehicle (e.g., vehicle body) further includes a power management module configured to regulate energy usage of the body systems and/or to record and track electrical energy usage in the body systems.

A vehicle-deployable enclosure assembly for deployment on a supporting surface using a lifting vehicle may include an enclosure base which is deployable between a collapsed configuration and an extended, enclosure-supporting configuration. An enclosure may be carried by the enclosure base. At least one attachment system may be provided on the enclosure. The at least one attachment system may be configured to facilitate attachment of the enclosure to the lifting vehicle. The enclosure base may be configured to deploy from the collapsed configuration to the extended, enclosure-supporting configuration in which the enclosure base supports the enclosure over the supporting surface responsive to lifting of the enclosure by operation of the lifting vehicle.

Loader apparatus configured for standing operator control are disclosed. The loader apparatus may include a loader adapted to carry a tool that is moveable between a down position and a vertically raised position. One or more linkages are connected to the first side of the loader support and connected to the loader. The apparatus includes a control station having operator controls for propelling the loader apparatus forward and for raising and lowering the loader. The apparatus includes an operator platform for standing operation of the operator controls of the control station.

A refuse vehicle has a chassis supporting a plurality of wheels, as well as a motor. A vehicle body is also supported by the chassis and defines a receptacle for storing refuse. A lifting system is coupled to the vehicle body and is movable between a first position and a second position vertically offset from the first position. The refuse vehicle also has a processing unit in communication with the lifting system and the motor. The processing unit is configured to access and toggle through a plurality of preset operational modes stored within a memory to adjust performance parameters of the refuse vehicle.

A refuse vehicle has a chassis supporting a plurality of wheels, as well as a motor. A vehicle body is also supported by the chassis and defines a receptacle for storing refuse. A lifting system is coupled to the vehicle body and is movable between a first position and a second position vertically offset from the first position. The refuse vehicle also has a processing unit in communication with the lifting system and the motor. The processing unit is configured to access and toggle through a plurality of preset operational modes stored within a memory to adjust performance parameters of the refuse vehicle.

A container assembly includes a container, a collection arm assembly, a locking mechanism, and a controller. The container has a front wall, a rear wall, a first sidewall, and a second sidewall cooperatively defining an internal cavity. The collection arm assembly is slidably coupled to the container such that the collection arm assembly is selectively extendable laterally outward from the container. The collection arm assembly includes a retaining pocket. The locking mechanism includes a latch and an actuator. The latch is positioned to selectively engage with the retaining pocket of the collection arm assembly. The actuator is positioned to selectively reconfigure the latch between an unlocked position and a locked position. The controller is configured to engage the actuator to selectively reconfigure the latch into the locked position and thereby prevent the collection arm assembly from extending laterally outward from the container.

A container assembly includes a container, a collection arm assembly, a locking mechanism, and a controller. The container has a front wall, a rear wall, a first sidewall, and a second sidewall cooperatively defining an internal cavity. The collection arm assembly is slidably coupled to the container such that the collection arm assembly is selectively extendable laterally outward from the container. The collection arm assembly includes a retaining pocket. The locking mechanism includes a latch and an actuator. The latch is positioned to selectively engage with the retaining pocket of the collection arm assembly. The actuator is positioned to selectively reconfigure the latch between an unlocked position and a locked position. The controller is configured to engage the actuator to selectively reconfigure the latch into the locked position and thereby prevent the collection arm assembly from extending laterally outward from the container.

A grasping mechanism for an agricultural bale wagon has a fixed grasping arm and a movable grasping arm. The movable grasping arm is translatable toward and away from the fixed grasping arm. The movable grasping arm can be rotated to define varying angular relationships between the fixed grasping arm and the movable grasping arm. Rotation and translation of the movable grasping arm are effected by an actuator. A resilient bumper between the fixed grasping arm and movable grasping arm is adjustable automatically to span the adjusted width between the fixed grasping arm and movable grasping arm.

A vehicle includes a chassis, a body coupled to the chassis, and a lift assembly coupled to at least one of the chassis or the body. The lift assembly includes a first lift arm and a second lift arm. The first lift arm includes a first arm portion, a second arm portion interfacing with the first arm portion, a first actuator positioned to facilitate repositioning the second arm portion relative to the first arm portion, and a second actuator positioned to pivot the first arm portion. The second lift arm includes a third arm portion, a fourth arm portion interfacing with the third arm portion, a third actuator positioned to facilitate repositioning the fourth arm portion relative to the third arm portion, and a fourth actuator positioned to pivot the second arm portion.