A cart includes a body portion forming a receptacle. A lid is pivotable relative to the body portion. A lock assembly includes a hasp fixed relative to one of the lid or the body portion. A lock is fixed relative to the other of the lid or the body portion and includes a catch for engaging the hasp and an actuator in electrical communication with a controller. The actuator is configured to actuate the catch to selectively secure the hasp relative to the lock.

Waste chute devices and methods for using the same are provided. In some embodiments, a method for operating waste chutes comprises: receiving, using a hardware processor of a waste chute device, an identity associated with a user of the waste chute device; in response to receiving the identity associated with the user, allowing, using the hardware processor, a door of the waste chute device to be opened; determining, using the hardware processor, a number of items and at least one type associated with the items that have been placed in an opening of the waste chute device; determining, using the hardware processor, that the door of the waste chute device has been closed; updating, using the hardware processor, information associated with the user based on the number of items and the at least one type of items that have been placed in the opening of the waste chute device; and providing, using the hardware processor, the user with the updated information.

The present invention discloses a load collecting device comprising: a case having an input port formed on one side thereof into which a load is put; a collecting unit disposed inside the case, and having an open top and an accommodation space which accommodates the load; an input unit arranged adjacent to the input port in the case, selectively rotating to open the input port, and transferring the load to the collecting unit; a pressing unit disposed on the top of the collecting unit, and of which at least a part of selectively lowers to pressurize the load accommodated in the collecting unit; and a sensing control unit sensing a load amount of the load accommodated in the collecting unit and controlling the pressing unit so as to selectively press the load.

A secured “smart” container is disclosed for collecting green waste products including operational functions for collection, video surveillance and monitoring capacity. The secured “smart” container may include one or more programmable logic controllers. Operational functions are performed by electrical components including sensors to determine green waste deposits characteristics and contents. Operational functions are further adapted to send and receive data, operationally wirelessly, and configured and adapted to utilize solar derived electric power and, optionally, electric power from other sources. Embodiments provide constant 24 hour/7 days a week video surveillance and alert monitoring capabilities. Disclosed systems and methods also include collection and transportation of waste contents from the container to a processing subsystem. Additionally, disclosed systems may also include a monitoring system for monitoring the collection of green waste product, delivery of the same to the processing subsystem and tracking to and throughout final processing of the green waste product and handling personnel.

A resource collection apparatus is an apparatus for collecting waste reusable as a resource. The resource collection apparatus includes an opening associated with a predetermined sorting type, an opening/closing unit configured to open and close the opening, a first detector configured to perform an operation to detect a target waste belonging to a user, and a controller configured to specify a sorting type into which the target waste is to be sorted, by using a result of the detection by the first detector. The controller switches the opening/closing unit from a closed state to an open state when the specified sorting type matches the sorting type associated with the opening.

A pair of devices includes a first device and a second device that communicate lock control signals. The first device can have both a reader component and a control module that controls both (1) a first operation of the first device (such as a sensor control) and (2) a first locking component of the first device for accessing a first door of the first device. A second device can be in communication with the first device. The second device can have a second locking component for the second device for accessing a second door of the second device. The second device in one aspect does not having a reader component or a control module that independently controls the second locking component.

The garbage box includes an opening-closing unit on a predetermined surface, and the garbage box is installed such that the opening-closing unit faces a base surface with a predetermined interval from the base surface, the base surface being a floor surface or a ground surface. The garbage box opens the opening-closing unit when the garbage box detects that an autonomous mobile robot has come to a predetermined position in a vicinity of an installation position of the garbage box.

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 secured “smart” container is disclosed for collecting green waste products including operational functions for collection, video surveillance and monitoring capacity. The secured “smart” container may include one or more programmable logic controllers. Operational functions are performed by electrical components including sensors to determine green waste deposits characteristics and contents. Operational functions are further adapted to send and receive data, operationally wirelessly, and configured and adapted to utilize solar derived electric power and, optionally, electric power from other sources. Embodiments provide constant 24 hour/7 days a week video surveillance and alert monitoring capabilities. Disclosed systems and methods also include collection and transportation of waste contents from the container to a processing subsystem. Additionally, disclosed systems may also include a monitoring system for monitoring the collection of green waste product, delivery of the same to the processing subsystem and tracking to and throughout final processing of the green waste product and handling personnel.

A waste collecting device includes an inlet unit, an acquisition unit configured to acquire waste information on waste thrown into the inlet unit, and a control unit configured to specify a category of the waste based on the waste information, determine whether the category of the waste matches a predetermined category, and output a determination result via an output unit.