Method for handling waste material in a pneumatic pipe transport system, wherein waste material is fed in from an input point into conveying piping, and conveyed in the conveying piping, mainly by the aid of suction/a pressure difference and/or a flow of transporting air, onwards to a separating device (1), in which the waste material to be transported and the transporting air separate from each other, from which separating device the waste material is transferred onwards to a separate waste container (26). Waste material is transferred, or is transferred and compressed to become denser, from the separating device (1) into a separate waste container (26) in a connecting channel (9) arranged between them with a transfer member (10) from the input aperture (8) of the connecting channel towards the output aperture (9′) and onwards into a separate waste container (26), and in which method the connection from the separating device (1) to the connecting channel (9) is closed at least during the detachment of the waste container (26). The invention also relates to an apparatus.

A trash compacting apparatus comprising a container, an air pump, one or more inflatable air bladders, a controller unit, and an interface unit is disclosed herein. The apparatus may further comprise an air distributor. The apparatus may operate as a standard trash container and may further comprise a lid. The apparatus may be operated by the user or by a programmable controller unit to inflate the air bladders, thereby compressing trash contained within the apparatus and reducing the total volume of the trash.

A system for ejecting a bale from a baler, wherein the ejection process is controlled by a control unit with input from various sensors and from a remote operator located on a tractor. The control unit automatically positions a chute, controls a power take-off from the tractor, depressurizes and opens a chamber door, ties the bale, selects and causes ejector teeth to project into a forming chamber to engage the bale, causes the ejector teeth to move toward a discharge outlet such that the engaged bale moves with them toward and through the discharge outlet, and determines when the bale has fully ejected from the baler. The remote operator may choose to eject only the bale or to eject the entire contents of the forming chamber, and if the former, the control unit determines the bale's length and selects a subset of the ejector teeth that corresponds to that length.

A compactor includes a frame supporting a first roller assembly and a second roller assembly. At least one of the first roller assembly and the second roller assembly is moveable relative to the frame in a motion that includes an upward vertical component and a downward vertical component. An actuator is coupled to at least one of the first and second roller assemblies and is operable to repeatedly move at least one of the roller assemblies relative to the frame in both the upward vertical component and the downward vertical component to oscillate the roller assemblies relative to each other.

A self-propelled baling vehicle for forming a bale of material includes a drive system for propelling the baling vehicle, a baling system for forming the bale, and a control system coupled to the drive system and the baling system. The control system includes a controller configured to determine a proposed location for ejection of the bale, operate the drive system to maneuver the baling vehicle from a first position to a second position for ejection of the bale at the proposed location, operate the baling system to eject the bale at the proposed location, and operate the drive system to maneuver the baling vehicle back to the first position.

A wrapping system includes: a material roll configured to hold a roll of wrapping material; a knife assembly comprising a movable knife that is configured to cut wrapping material that comes off the material roll; a sensor associated with the material roll and configured to output a drawn material signal; and a controller. The controller is configured to: receive the drawn material signal; determine a length of wrapping material that is drawn from the material roll; output a cut signal to the knife assembly when the drawn length of wrapping material reaches a defined length; determine a length of wrapping material that is drawn from the material roll after outputting the cut signal; and output an excessive wrap signal when the length of wrapping material drawn after outputting the cut signal exceeds a threshold length.

Systems, methods, and apparatuses for controlling electrically-powered trash receptacles and monitoring fullness levels. The system can include a storage enclosure and a bin contained inside the storage enclosure, the bin configured to receive and store items deposited in the storage enclosure, wherein an inside portion of the bin is at least partially covered by a bag placed inside the bin to hold the items deposited in the storage enclosure. The system can also include a sensor configured to sense a content fullness state of the bin and a processor configured to control operations performed by the sensor. In addition, the system can include a sleeve configured to be installed over an inside portion of the bin and the bag, the sleeve at least partially restricting a movement of the bag.

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 baling system comprising a first bale-forming area configured to form a first series of first individual bales, and a second bale forming-area configured to from a second series of second individual bales. The baling system additionally comprises a bale accumulator configured to receive the first and second individual bales from said first and second bale-forming areas and to manipulate the first and second individual bales into a group of four or more bales.

A baler implement includes a housing that defines a baling chamber for forming crop material into a bale. The baler implement further includes a knotter system having a component that is moveable between a standby position and a wrapping position while wrapping the bale. A knotter sensor communicates a knotter engagement signal in response to movement of the component. A reader is in communication with the knotter sensor and is emits an interrogation signal for reading an identification tag on the bale. The reader emits the interrogation signal for a predefined period of time in response to the knotter engagement signal from the knotter sensor indicating movement of the component of the knotter system while wrapping the bale with the strand material.