A grabber assembly has a beam assembly with a bracket. A grabber gear assembly is coupled with the bracket. The grabber gear assembly has a pair of gear mechanisms coupled with the bracket. Each gear mechanism has a shaft and a pair of thrust bearings, one at each end of the shaft. A grabber arm mounting pad is coupled with each shaft. A gear section is coupled with each shaft. The gear sections of each shaft mesh with one another to drive the grabber arm mounting pads. An actuating driver is coupled with one of the shafts to drive the grabber gear assembly and move the arms between an open and grasping position.

A fully-electric lift assembly for a refuse vehicle includes a track, a carrier, and a push chain. The track includes multiple channels that extend along an entire length of a path of the track. The carrier is configured to translate along the path of the track. The carrier includes multiple slidable members, each slidable member configured to engage the track at a corresponding one of the channels. The push chain is configured to couple with the carrier at a first end and be driven by an electric motor. The push chain is configured to exert a pushing force on the carrier to drive the carrier to ascend along the track.

A refuse vehicle includes a body defining a refuse compartment, a refuse collection arm configured to engage and lift a refuse container, an object detection system configured to provide object detection data relating to locations of objects relative to the refuse vehicle, and a controller. The controller is configured to use the object detection data to determine if the refuse container is present within an aligned zone relative to the refuse vehicle. The aligned zone represents a range of locations in which the refuse collection arm is capable of engaging the refuse container. In response to a determination that the refuse container has been detected by the object detection system but is not within the aligned zone, the controller is configured to provide instructions to an operator that, when performed by the operator, cause the refuse vehicle to move such that the refuse container enters the aligned zone.

A vehicle system includes a refuse vehicle, a carry can, and an electric energy system. The refuse vehicle includes a chassis, a body assembly coupled to the chassis, and a lift assembly. The body assembly defines a vehicle refuse compartment. The carry can is selectively couplable to the lift assembly. The carry can includes a container defining a container refuse compartment and an articulating collection arm coupled the container. The articulating collection arm has an actuator positioned to facilitate manipulating the articulating collection arm. The electric energy system is at least one of positioned on the refuse vehicle or positioned on the carry can. The electric energy system is configured to facilitate operating the actuator of the articulating collection arm.

A refuse vehicle comprises a chassis, a body assembly, a power source, and a side-loading lift assembly. The chassis is coupled to a plurality of wheels. The body assembly is coupled to the chassis and defines a refuse compartment configured to store refuse material. The side-loading lift assembly comprises a refuse container engagement mechanism and at least one electrically-driven actuation mechanism. The refuse container engagement mechanism is powered by the power source and is configured to selectively engage a refuse container. The at least one electrically-driven actuation mechanism is powered by the power source and is configured to selectively actuate the side-loading lift assembly between an extended position, a retracted position, and a refuse-dumping position.

A refuse vehicle comprises a chassis, a body assembly, a battery system, and a side-loading lift assembly. The body assembly is coupled to the chassis and defines a refuse compartment configured to store refuse material. The battery system is configured to be charged via at least one of an on-board electrical energy generator, an external power source, or a power regenerative braking system. The side-loading lift assembly comprises a refuse container engagement mechanism and at least one electrically-driven actuation mechanism. The refuse container engagement mechanism is configured to selectively engage a refuse container. The at least one electrically-driven actuation mechanism is powered by the battery system and is configured to selectively actuate the side-loading lift assembly between an extended position, a retracted position, and a refuse-dumping position.

A vehicle includes a chassis, a body, a lift assembly coupled to the body, a collection arm assembly coupled to the lift assembly and including a pair of interface members configured to engage an object, an object detection system configured to provide object detection data, and controller. The controller is configured to receive an indication, based on the object detection data, that the object is within an aligned zone relative to the body, determine an initial location of the object relative to the body, move the lift assembly so that the pair of interface members are aligned to engage the object, actuate the collection arm assembly to engage the pair of interface members with the object, and instruct the lift assembly to raise the object relative to the body.

A mechanical arm designed to provide automated garbage collection with smooth, constant movement (i.e. movement that has minimal jerk/shock) thereby resulting in limited shock stress on the components and leading to high durability. The mechanical arm including a horizontal displacement system having a plurality of sections rollingly engaged to one another and a motor mounted to an immobile section for drivingly extending section in a generally horizontal orientation, a vertical displacement system having a plurality of masts rollingly engaged to one another and a motor mounted to a first mast for drivingly extending a second mast in a generally vertical orientation, and/or a grabber system having a plurality of fingers mounted to a frame and operated by a single motor.

Operating a refuse collection vehicle to collect refuse from a refuse container includes positioning a refuse collection vehicle with respect to a refuse container to be emptied, and manually engaging a switch to initiate a dump cycle to be performed by the refuse collection vehicle on the refuse container. The dump cycle includes engaging the refuse container with a portion of the vehicle, lifting the engaged refuse container to a dump position, and moving the refuse container to release contents of the refuse container into a hopper of the refuse collection vehicle. The dump cycle continues to completion as long as the switch remains manually engaged.

A grabber arm mechanism for use as part of a refuse collection vehicle has a mismatched pair of grabber fingers which are both arcuate, with a first grabber finger being longer than a second grabber finger. Due to the mismatch in size in the first grabber finger and the second grabber finger, the grabber mechanism is capable of handling a larger range of container sizes thereby providing increased capabilities for a refuse collection vehicle. The configuration of the fingers (mismatched) also provides advantages when dealing with smaller containers.