Systems, methods, and computer-readable storage media for controlling electrically-powered trash compactors and receptacles. The system first receives data associated with a storage receptacle configured to communicate with the system via a network, wherein the data is received from a server storing information transmitted by the storage receptacle, the storage receptacle having an energy storage for powering operational functions performed by the storage receptacle. The system then identifies a parameter of the storage receptacle associated with an operational function of the storage receptacle, and transmits a signal to the storage receptacle for modifying the parameter based on the data associated with the storage receptacle to yield a modified operation of the storage receptacle.

An embodiment method for controlling a physical object to be shared by several potential users and in an enclosure in an open state or in a closed state includes detecting a presence or an absence of the object in the enclosure in the closed state via a first wireless link between the object and a reader situated in the enclosure, the first wireless link being contained in the enclosure in the closed state. The method also includes transmitting a first information item representative of the presence or of the absence of the object in the enclosure to a computer server via a second link and an internet network, the computer server being accessible via a website configured to be managed by an administrator.

Systems and methods for managing the collection of contents from geographically distributed containers are disclosed herein. The systems can have a sensor in the container in data communication with a server system. The sensor can send data regarding the volume of contents in the container to the server system. The server system can then create routing information for a fleet of vehicles to empty the containers based on which containers are full enough for immediate collection, other predictive data for less full containers, and traffic and other routing factors for the vehicles. The server system can then transmit the routing information to the vehicles, track the vehicles, and prepare reports.

An embodiment relates to a trash collection device comprising a trash receptacle with a unique identification and an opening to receive a class of trash; an identification scanner for recognizing a user; a trash item counter; a fill level sensor; a display configured to interact with the user; a compactor; a solar panel configured to charge a battery; a data communicator configured to communicate date to a cloud storage; a processor configured to generate incentive for the user; wherein the trash collection device is configured to be modular and configurable to connect with another similar trash collection device to enable to collect additional trash class and is configured to interact with each other through a common software. The device, method and system are further used to generate recycling analytics by using the stored data to provide incentives to users and to facilitate planning of downstream operations.

A solid waste bag unit for solid waste of an analyzer is disclosed. The solid waste bag unit comprises a bag, and an insert, wherein the insert is arranged within the bag. Further, an analyzer and a method for removing solid waste of an analyzer are disclosed.

A storage receptacle can include a storage bin and a pedal mounted to the receptacle. The pedal can rotate downward when pressure is applied in order to pull on a first cable coupled to the pedal. The first cable is connected to a spring, and the spring is connected to a second cable. The second cable connects the spring to a door via an upper pulley of the receptacle. The second cable causes the door to open when the second cable is pulled based on force applied to the pedal. A bottom pulley can be coupled to the pedal via the first cable and configured to translate an upward pull of the first cable to a downward pull of the spring and second cable. The spring controls the motion of the door such that the door does not open too quickly upon a force being applied to the pedal.

A series of techniques incorporated in two sensing methods that enable fullness detection whilst minimizing the current consumption of the battery operated wireless electronic circuitry that implements the detection.

A robotic drive system can be attached to a garbage container. A computing device can be configured to determine a travel path for the robotic drive system to travel to a location designated for garbage pickup. The computing device can be configured to cause the robotic drive system to move to be proximate to a location designated for garbage pickup.

A refuse collection apparatus is disclosed. A refuse collection apparatus according to one embodiment of the present invention a main body unit into which a refuse is inserted, a refuse compression unit installed in the main body unit and configured to compress the refuse inserted into the main body unit and a movement range detection unit located inside of the main body unit and configured to detect a movement range of the refuse compression unit.

A storage receptacle can include a storage bin and a pedal mounted to the receptacle. The pedal can rotate downward when pressure is applied in order to pull on a first cable coupled to the pedal. The first cable is connected to a spring, and the spring is connected to a second cable. The second cable connects the spring to a door via an upper pulley of the receptacle. The second cable causes the door to open when the second cable is pulled based on force applied to the pedal. A bottom pulley can be coupled to the pedal via the first cable and configured to translate an upward pull of the first cable to a downward pull of the spring and second cable. The spring controls the motion of the door such that the door does not open too quickly upon a force being applied to the pedal.