A method and system for compacting waste materials in a collection container. The container can be a freestanding waste container, a self-container compaction container, or a container on a waste collection vehicle. A hydraulically operated compactor blade is positioned in the raised upper portion of the container with its bottom edge a distance above the floor. A platform with a hinged portion can be included to divide the container volume into two separate compartments in order to collect different types of waste materials.

A refuse vehicle according to the present disclosure includes a chassis, a cab coupled to the chassis, a refuse compartment body coupled to the chassis and defining a hopper and a storage volume; and a packer assembly including a packer body coupled to at least one actuator and disposed at least partially within the refuse compartment body, the packer body movable between at least a portion of the hopper and at least a portion of the storage volume, and an enclosure that extends along the refuse body parallel to the chassis, the enclosure at least partially separating the at least one actuator from the refuse compartment.

A refuse vehicle comprises a chassis, a body assembly, a power source, a tailgate, and a refuse interaction mechanism. The body assembly is coupled to the chassis and defines a refuse compartment configured to store refuse material. The refuse interaction mechanism comprises a refuse interaction element and an electric motor. The refuse interaction element is configured to selectively apply a force onto the refuse material within the refuse compartment. The refuse interaction element is moveable between a receiving position, in which the refuse compartment is configured to receive refuse material, and a force-exerting position, in which the refuse interaction element is configured to exert the force on the refuse material stored within the refuse compartment. The electric motor is powered by the power source and configured to selectively move the refuse interaction element between the receiving position and the force-exerting position.

A refuse collection vehicle includes a body having a storage compartment and a packer system. The storage compartment includes a floor. The packer system includes an ejector, two or more helical band actuators, and a driver. The helical band actuators each include a drive cylinder base, a helical band drive cylinder, and a drive cylinder receptacle coupled between the helical band drive cylinder and the ejector. The driver is commonly coupled to the helical band actuators and operable to extend and retract the helical band drive cylinders. The helical band actuators are operable to advance the ejector such that refuse is compacted in the storage compartment or ejected from the storage compartment.

A refuse vehicle comprises a chassis, a body assembly, and a refuse interaction mechanism. The body assembly is coupled to the chassis and defines a refuse compartment configured to store refuse material. The refuse interaction mechanism comprises a refuse interaction element, an electrically driven actuator, and an impulse generator. The refuse interaction element is configured to selectively apply a force onto the refuse material within the refuse compartment. The electrically driven actuator is configured to selectively move the refuse interaction element between the receiving position and the force-exerting position. The impulse generator is configured to selectively apply linear impulse to the refuse interaction element.

The present invention is directed toward a new and improved compactor or packer. The compactor, which may be used to compact refuse, includes a container, a track disposed within the container, and a ball screw rotatably disposed within the track. The compactor further includes a ball nut operatively coupled around the ball screw, where rotation of the ball screw causes the ball nut to move along or traverse the ball screw. A packer blade is coupled to the ball nut via a floating interface. Movement of the ball nut long the ball screw due to rotation of the ball screw forces the packer blade to move within the container. The floating interface allows the packer blade to float within the container with respect to the ball nut to reduce the likelihood of binding of the ball nut on the ball screw as the packer blade traverses within the container.

A method and system for compacting waste materials in a collection container. The container can be a freestanding waste container, a self-contained compaction container, or a container on a waste collection vehicle. A hydraulically operated compactor blade is positioned in the upper portion of the container with its bottom edge a distance above the floor. A door member can be provided in the rear wall of the collection container. The compactor blade can be in its rest position relative to the top opening. The container member can be positioned or located on a trailer or truck-type vehicle and adapted to be tilted for evacuation of materials collected therein.

A system for compacting rubbish, including a frame having a front wall, a carrier to be moved in a forwards-backwards direction relative to the frame, an upper scoop pivotably mounted on the carrier about a first horizontal axis and having an upper face for milling rubbish, and a lower scoop pivotably mounted on the upper scoop about a second horizontal axis, and having a lower milling face rubbish. The upper and lower scoops are to take a downwardly deployed position when their respective milling faces face the front wall. The carrier is to be moved forwards when the upper and lower scoops are in deployed position, in such a way as to compact the rubbish between the milling faces and the front wall. In the deployed position, a projection of the upper milling face in a transverse plane has a surface greater than or equal to a projection of the lower milling face in the transverse plane.