A rear loading refuse vehicle includes a tailgate coupled to a rearward end of the body. The tailgate includes a modular refuse packing assembly removably mounted therein and configured to compact refuse received in a hopper into a storage chamber located in the body. The modular refuse packing assembly may include a frame supporting an actuator and a blade. The frame is removably coupled to the tailgate. The actuator is configured to move the blade between extended and retracted positions and thereby compact the refuse received in the hopper.

A rear loading refuse vehicle includes a tailgate coupled to a rearward end of the body. The tailgate includes a modular refuse packing assembly removably mounted therein and configured to compact refuse received in a hopper into a storage chamber located in the body. The modular refuse packing assembly may include a frame supporting an actuator and a blade. The frame is removably coupled to the tailgate. The actuator is configured to move the blade between extended and retracted positions and thereby compact the refuse received in the hopper.

An ejector for a refuse vehicle including a structural frame, a first shoe, and a second shoe. The structural frame includes a first side plate offset from a second side plate, and the distance between the first side plate and the second side plate defines a side plate spacing. The first shoe is coupled to the first side plate and includes a first surface configured to interface with a first ejector track. The second shoe is coupled to the second side plate and includes a second surface configured to interface with the second ejector track. A lateral spacing between the first surface and the second surface is less than or equal to the side plate spacing such that loading imparted on the structural frame is transmitted directly into the first ejector track and the second ejector track.

A refuse vehicle includes a chassis and a body assembly. The body assembly includes a series of panels configured to contain a volume of refuse therein and an ejector. The panels define a hopper volume and a storage volume. The ejector is configured to fully eject refuse from the storage volume. The ejector includes a wall at least partially defining an opening and a coupling pivotally and fixedly coupling a panel to the wall. The wall is movable within the storage volume. The panel is repositionable relative to the wall between a closed position and an open position. The panel extends at least partially across the opening when in the closed position and is angularly offset relative to the closed position when in the open position.

A solid waste displacement system, more specifically a system affixed to a mobile structure (such as, for instance, a truck bed, a trailer, and the like), provided. Such a system includes a drive shaft coupled to a movable wall assembly that provides sufficient force to push solid waste from the mobile structure along the drive shaft when operated. The drive shaft may be a chain driven device or any other like mechanism that accords movement and force to the movable wall assembly for such a solid waste displacement purpose. The device as well as the method of utilizing such a device on and/or within a mobile structure are encompassed herein.

A refuse vehicle includes a chassis, an energy storage device, a body, a first electric power take-off system, and a second electric power take-off system. The energy storage device is supported by the chassis and is configured to provide electrical power to a prime mover. Activation of the prime mover selectively drives the refuse vehicle. The body is supported by the chassis. The first electric power take-off system is coupled to at least one of the body and the chassis, and includes a first motor that is configured to drive a first hydraulic pump to convert electrical power received from the energy storage device into hydraulic power. The second electric power take-off system is coupled to at least one of the body and the chassis, and includes a second motor that is configured to drive a second hydraulic pump to convert electrical power received from the energy storage device into hydraulic power.

A refuse vehicle includes a chassis, an energy storage device, a body, a first electric power take-off system, and a second electric power take-off system. The energy storage device is supported by the chassis and is configured to provide electrical power to a prime mover. Activation of the prime mover selectively drives the refuse vehicle. The body is supported by the chassis. The first electric power take-off system is coupled to at least one of the body and the chassis, and includes a first motor that is configured to drive a first hydraulic pump to convert electrical power received from the energy storage device into hydraulic power. The second electric power take-off system is coupled to at least one of the body and the chassis, and includes a second motor that is configured to drive a second hydraulic pump to convert electrical power received from the energy storage device into hydraulic power.

An apparatus for processing material in connection with a pneumatic material conveying system includes a waste container/separating device, into which material is configured to be conducted from a conveying pipe of the pneumatic material conveying system via an inlet aperture and which is configured to be connected to a partial vacuum generator. The apparatus further includes a press device/compactor device, which is arranged to act on the material (w) conducted into the waste container/separating device, via at least one aperture formed in the container, and that at least one wall that is transverse with respect to the input direction of the material is arranged in the container space of the waste container/separating device, which wall is configured to guide the material into the operating range in the container space of the compressor of the press device/compactor device.

An unloading system comprises an upper-opening chamber for receiving airplane-derived refuse; a chute; a chute-connected safety gate which is settable in falling preventing relation with respect to an access door of an airplane from which the refuse is unloadable into the chute and to the chamber; and an air brake assembly for immobilizing the safety gate when the chute ceases to be vertically displaced. A compacting system comprises a main platen mount with an occluding surface for occluding the opening; an auxiliary platen mount for movably supporting the main platen mount; a holder assembly underneath the auxiliary platen mount; and force transmitting elements always retained within a compaction chamber interior. The main platen mount is linearly driven between a first position completely forwardly of the opening and a second position at which the opening is completely occluded, and is additionally driven to discharge the received refuse. Methods are also disclosed.

A refuse vehicle includes a cab and a body assembly disposed behind the cab. The body assembly includes an ejector and a body at least partially defining a hopper volume and a storage volume. The ejector includes a wall at least partially defining an opening and a coupling pivotally and fixedly coupling a panel to the wall. The wall is movable within the storage volume between a frontmost position and a rearmost position. The panel extends at least partially across the opening when in a closed position. The panel is angularly offset relative to the closed position when in the open position. The ejector is configured to fully eject refuse from the storage volume when the wall is in the rearmost position. The hopper volume extends between the wall and the cab when the wall is in the frontmost position.