A compactor trolley for aeronautical applications, more particularly a trolley provided with a drawer having a door with a safety closing system that incorporates a flap for direct access to the waste storage compartment, without the need to pull out the drawer and/or open the door.

A filling device (3) and a filling method for fibrous material (6) on a bale press (1). The filling device (3) is arranged between a fiber supply (2) and a pressing device (5) of the bale press and comprises a collecting chamber (9) for the fibrous material (6) with a supply opening (16) as well as a discharge opening (17) with a controllable closure (18). A driven slide (25) of an integrated precompression device (4) is movable in a reversing manner between the openings (16, 17), which precompresses the collected fibrous material in one or more stages in the collection chamber (9) before collected fibrous material is transferred to the pressing device.

A system for recompressing a round bale into a square bale includes a bottom platen to receive the round bale and a movable platen translatable relative to the bottom platen. The system includes an upper platen rotatable relative to the bottom platen. The upper platen is rotatable between a first position to receive the round bale between the bottom platen, the movable platen and the upper platen, and a second position in which the upper platen cooperates with the movable platen and the bottom platen to recompress the round bale into the square bale.

A trash compactor may include a frame, a cavity, a trash receptacle, a platen movable to compress trash collected in the trash receptacle, a set of linkages and a drive mechanism configured to drive said platen up and down, the drive mechanism further configured as one of the link elements, and a platen guide mechanism configured to restrict the motion of the platen in an up and down manner.

Systems, methods, and computer-readable storage media for dynamically adjusting sensors for use in compactors and receptacles. A receptacle first sends a signal from a transmitter on a first module in a receptacle to a receiver on a second module in the receptacle, wherein the first module is located on a first inner wall of the receptacle and the second module is located on a second inner wall of the receptacle, and wherein at least part of the first module and the second module is located a distance above a bin inside the receptacle. Next, the receptacle determines a signal-detection characteristic including a signal detection status or a number of signal pulses associated with a signal detection. Based on the signal-detection characteristic, the receptacle determines an operating condition of the receptacle, the operating condition including a fullness level or an obstruction level associated with the first or second sensors.

A pressing device for pressing meat products, in particular frozen and/or partly frozen meat products, preferably fresh meat products and/or bacon, comprises a pressing chamber which extends along a longitudinal axis and into which a product to be pressed can be inserted, wherein the pressing chamber comprises at least one counter-element and at least one contact element, which is movable in the direction of the counter-element, that cooperate such that the product inserted into the pressing chamber can be compressed between the at least one counter-element and the at least one contact element; and wherein the pressing device comprises at least one servomotor that is configured to move the at least one contact element.

In a method of pressing and processing meat products, in particular frozen and/or partly frozen meat products, preferably fresh meat products and/or bacon, the products are inserted into a pressing chamber of a pressing device and are pressed in the pressing chamber by at least one displaceable contact element, with the contact element being moved by means of a servomotor.

A system for recompressing a round bale into a square bale includes a bottom platen and a fixed platen proximate the bottom platen. The system includes a transfer table to receive the round bale. The transfer table is movable relative to the bottom platen to transfer the round bale to the bottom platen and to recompress the round bale. The system includes an upper platen rotatable relative to the bottom platen and the fixed platen. The upper platen is rotatable between a first position to receive the round bale between the bottom platen, the fixed platen and the upper platen, and a second position in which the upper platen cooperates with the transfer table to recompress the round bale into the square bale.

A compaction material feeding device for a vertical baling press, the compaction material feeding device having a compaction material compailinent and a conveyor for feeding compaction material from the compaction material compailinent to a loading opening of the associated baling press. In the compaction material feeding device the compaction material compailinent is limited by a web-shaped carrier element having side wall segments and having a floor segment, as well as at least two fixed second side walls situated opposite one another. The carrier element can be lifted by a lifter device. In a maximally lifted end position of the carrier element, this element is drawn tight, and a compaction material transfer region of the compaction material feeding device is covered and closed by one of the side wall segments of the carrier element. In addition, a baling press is provided having a compaction material feeding device as described.

Systems, methods, and computer-readable storage media for dynamically adjusting sensors for use in compactors and receptacles. A receptacle first sends a signal from a transmitter on a first module in a receptacle to a receiver on a second module in the receptacle, wherein the first module is located on a first inner wall of the receptacle and the second module is located on a second inner wall of the receptacle, and wherein at least part of the first module and the second module is located a distance above a bin inside the receptacle. Next, the receptacle determines a signal-detection characteristic including a signal detection status or a number of signal pulses associated with a signal detection. Based on the signal-detection characteristic, the receptacle determines an operating condition of the receptacle, the operating condition including a fullness level or an obstruction level associated with the first or second sensors.