Device (100) for pressing organic material out of waste, comprising: a pressing chamber (3) and a first pressing member (4) for compacting introduced waste; a first feed opening (5) for feeding waste into the pressing chamber (4); perforations (6) for allowing air, moisture and organic material pressed out of introduced waste to escape from the pressing chamber (3), which perforations (6) are arranged in a wall (9) of the pressing chamber (3) and debouch in a surface (7) bounding the pressing chamber (3); and a discharge opening (8) for discharging from the pressing chamber (3) compacted waste from which air, moisture and organic material are at least partially removed and whereby the surface lies perpendicularly of the pressing direction of the first pressing member (4). Pressing perpendicularly of the surface (7) results in a more effective and efficient pressing. The device (100) preferably also comprises: a second feed opening (2) for feeding waste into the device (100); and an infeed chamber (13), which infeed chamber (13) is located between the first feed opening (5) and the second feed opening (2). A pre-compaction takes place during the displacement of waste fed into the infeed chamber (13) to the pressing chamber (3) via the first feed opening (5), this still further increasing the effectiveness, efficiency and yield of the pressing. Also method for pressing organic material out of waste by means of such a device.

A waste compaction system for a vehicle includes a moveable trolley for storing waste, and a docking station integratable into a cabin monument for inserting the trolley. The trolley includes a housing having an opening for inserting waste, a vacuum waste compacting mechanism inside the housing and a first suction port accessible from outside the housing, the first suction port being couplable with the vacuum waste compacting mechanism. The docking station and the trolley are adapted to each other such that the trolley is engageable with the docking station, and wherein the docking station includes a second suction port couplable with a suction line in the vehicle and the first suction port. Resultantly, a lightweight and efficient waste compaction system is provided, which allows moving the trolley for collecting waste inside a cabin of the vehicle.

A system includes a vehicle monument, a hose with a fluid line, and an adapter with a triggering unit and a housing, which has a fluid connection. The fluid connection couples to a fluid mating connection, wherein the monument has a fluid main valve and a control unit for controlling the fluid main valve, an inlet of the fluid main valve couples to a fluid suction source, and a first end of the hose connects to the monument such that a first end of the fluid line is coupled to a first outlet of the fluid main valve. A second end of the hose is connected to the adapter such that a second end of the fluid line is coupled to the fluid connection, and the control unit controls the fluid main valve based on a triggering signal from the triggering unit.

A system for compacting waste includes a trolley and a cabin monument. The trolley or the cabin monument has a compacting device. The compacting device includes a cover with a bellows that is arranged on the lower face of the cover and is designed to be movable between a folded-together position, in which the bellows interior has a first volume, and an unfolded position, in which the bellows interior has an enlarged second volume. By suctioning fluid from a container interior formed in the trolley by means of a first cover channel arranged in the cover of the trolley, the bellows can be moved into the unfolded position such that the bellows protrudes far enough into the container interior that the waste container and/or waste in the waste container is compacted.

A waste compaction apparatus may include a housing and a connector arm. The housing may define a drive chamber and a compaction chamber and the connector arm may include a drive piston portion movably positioned within the drive chamber and a compaction piston portion movably positioned within the compaction chamber. The drive chamber may be selectively fluidly coupleable to the near-vacuum of outer space, such that the compaction piston portion of the connector arm is configured to move within the compaction chamber to compact waste material contained within the compaction chamber in response to movement of the drive piston portion of the connector arm within the drive chamber.

A fully integrated, low maintenance, manually operated beverage container compacting system featuring a free-standing, user powered, enclosed, beverage container compactor and storage receptacle. The compactor includes a self retracting puncture mechanism to release pressure due to air and liquids in sealed containers prior to their compacting. The storage system includes double trap doors with gaskets to create a sealed storage receptacle that reduces odors. A first top trap door includes a rubber gasket to prevent liquids from being expelled out of the compactor; and a bottom trap door is configured for capturing escaped liquids. The bottom trap door is actuated into an open state at an end of a crushing stroke to drop the container into the storage receptacle after captured liquids have drained into a liquid capture container for improved cleanliness. A self reset mechanism renders the system to an initial state for a next user after compacting.

The present disclosure concerns units for treating used food packages, more specifically for separation and compactization of used capsules containing edible ingredients residues, such that the units are configured to receive and compact a stack of used food packages, as well as separate food substance residues from the packages during such compaction.

A super compactor receives a carbon-containing material and delivers a brick suitable as fuel for power generation. A compaction chamber receives the carbon-containing material and has at least one ram reciprocating along a travel path and exerting a predetermined amount of pressure on the carbon-containing material. The compaction chamber also has an end effector plate or a movable slide gate against which the carbon-containing material is compressed, promoting the removal of moisture from the carbon-containing material, and one or more dewatering apertures or a membrane permitting moisture to pass through but blocking the carbon-containing material. A collector captures the moisture that passes through the dewatering apertures or membrane. A power unit provides power to the at least one ram. A heated extrusion chamber receives the carbon-containing material from the compaction chamber and heats and compacts the carbon-containing material to bind the carbon-containing material into the form of a brick.

A super compactor receives a carbon-containing material and delivers a brick suitable as fuel for power generation. A compaction chamber receives the carbon-containing material and has at least one ram reciprocating along a travel path and exerting a predetermined amount of pressure on the carbon-containing material. The compaction chamber also has an end effector plate or a movable slide gate against which the carbon-containing material is compressed, promoting the removal of moisture from the carbon-containing material, and one or more dewatering apertures or a membrane permitting moisture to pass through but blocking the carbon-containing material. A collector captures the moisture that passes through the dewatering apertures or membrane. A power unit provides power to the at least one ram. A heated extrusion chamber receives the carbon-containing material from the compaction chamber and heats and compacts the carbon-containing material to bind the carbon-containing material into the form of a brick.

A press for processing organic waste has two plungers. Preferably, the plungers have rectangular cross sections. The two plungers are mounted in the press such that they are perpendicular to each other and have partially overlapping stokes. The press has walls that partially enclose a pressing chamber. The pressing chamber is as wide as one plunger on one side, and as wide as the other plunger on another side. In operation, one of the two plungers is used to optionally load organic waste into the pressing chamber, to partially enclose the pressing chamber while the waste is compressed, and to eject compressed waste from the pressing chamber. The other plunger is used to compress waste in the pressing chamber whereby a pressate is produced through perforations in a wall of the pressing chamber. The other plunger may also partially enclose the pressing chamber while compressed waste is ejected.