A lift assembly for a refuse vehicle includes a lift arm pivotally coupled to a body of the refuse vehicle and a pair of forks pivotally coupled to the lift arm, the pair of forks is configured to engage with a refuse container. The lift assembly further includes an electric lift arm actuator comprising an output shaft. The electric lift arm actuator may be communicably coupled to an electric energy system. The lift assembly further includes a pin coupled to the lift arm assembly and the electric lift arm actuator. The pin is configured to rotate about a pin axis. Rotation of the output shaft causes the lift arm assembly to rotate relative to the body via the pin.

An articulated front loader arm structure is provided for use with a conventional refuse collection vehicle having a conventional cab chassis. The articulated arm structure is controlled by a programmed logic controller (PLC) which for monitors and controls the movement of the front loader articulated arm structure. The PLC communicates with various cylinders and sensors to control the extension/retraction of the various cylinders associated with the various arm sections of the front loader arm structure during movement through both its container dump cycle and its container return cycle. The articulated arm structure allows the present front loader arm mechanism to both extend over a conventional cab chassis as well as to be stored on top of the refuse vehicle under the current legal height restriction of 13 feet, 6 inches.

A refuse vehicle includes a chassis, multiple tractive elements, a reach assembly, and a lift assembly. The multiple tractive elements are coupled with the chassis and configured to support the refuse vehicle. The reach assembly is coupled with the refuse vehicle. The lift assembly is coupled with the reach assembly. The lift assembly includes a track and a fully-electric grabber assembly. The track includes a straight portion and a curved portion. The fully-electric grabber assembly can ascend or descend the track and includes a carriage, a first grabber arm, a second grabber arm, and an electric motor. The carriage is configured to movably couple with the track. The first grabber arm and the second grabber arm are pivotally coupled with the carriage at opposite ends of the carriage. The electric motor is configured to drive the first grabber arm and the second grabber arm to rotate relative to the carriage.

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 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.

An attachment system for a vehicle includes a lateral member and a coupler. The coupler includes a first support coupled to the lateral member, a second support spaced from the first support, a resilient member disposed between the first support and the second support, and an adjuster configured to facilitate selectively reorienting the second support relative to the first support between a first position and a second position. The second support is configured to engage an interface of an attachment when selectively reoriented into the first position and disengage the interface of the attachment when selectively reoriented into the second position.

An intermediate container for a refuse vehicle where the container is positioned in front of the refuse vehicle is provided. A plurality of legs extends from the container toward the refuse vehicle. An attachment mechanism is on each leg to secure the legs to a front loading arm assembly of the refuse vehicle.

A refuse vehicle comprising a chassis, a body assembly coupled to the chassis, the body assembly defining a refuse compartment, one or more sensors coupled to the body and configured to provide data relating to the presence of an obstacle within an area near the refuse vehicle, a controller configured to receive the data from the one or more sensors, determine, using an obstacle detector and the data, the presence of an obstacle within the area and initiate a control action, wherein the control action includes at least one of controlling the movement of the refuse vehicle, controlling the movement of a lift assembly attached to the body assembly, or generating an alert.

A lifting arm assembly is movable between a grabbing position and tipping position and includes a static frame provided with a roller arrangement. A dynamic frame is mounted for vertical movement relative to the static frame. A grabber structure is provided with a pair of grabber arms configured for movement between a closed position and an open position. A linkage arrangement has a first end pivotally connected to the dynamic frame, and a second end pivotally attached to the grabber structure. The first end includes a set of teeth arranged in meshing engagement with the roller arrangement on the static frame. Movement of the dynamic frame relative to the static frame causes pivoting of the linkage arrangement resulting in lifting movement of the grabber structure along a curvilinear path between the grabbing position and the tipping position.

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.