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.

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 system for measuring a fill level of a trash can comprises a processor operable to receive a distance measurement from a network, wherein a sensor communicatively coupled to the processor through the network is operable to determine the distance measurement. The processor is operable to calculate a percentage of waste in the trash can based on the received distance measurement and a difference between a first setpoint and a second setpoint. The processor is operable to determine a threshold for a first period of time based on entity information. The processor is operable to compare the percentage of waste in the trash can to the threshold for the first period of time and to send an alert for display on a user device when the percentage of waste is greater than the threshold for the first period of time.

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 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 guide robot includes a lower module includes a wheel and a motor provided inside the lower module, and an upper module disposed at an upper portion of the lower module and including a trash can assembly and a display unit. The upper module includes a body part coupled to the upper portion of the lower module and a head part rotatably coupled to an upper portion of the body part. The body part includes a front case forming a front outer appearance of the body part and including the trash can assembly provided inside the front case, and a rear case forming a rear outer appearance of the body part and including the display unit. A garbage insertion part is provided at a portion of the front case corresponding to an upper portion of the trash can assembly to insert garbage into the trash can assembly.

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 multipurpose refuse receptacle comprising an outer shell defining an inner chamber, a receiving assembly disposed within the inner chamber, and a door assembly. The door assembly is movable between an open position and a close position. The receptacle has a basket carrier and a basket, the basket being disposable within the basket carrier. Further, a hydraulic lift assembly is operably coupled to the basket carrier, the hydraulic lift assembly having a pump assembly. A mechanism is operably coupled to the pump assembly and the door assembly, the mechanism being movable in a first direction. Wherein, when the mechanism is moved in the first direction the door assembly moves to the open position. Further wherein, when the mechanism is moved in the first direction, hydraulic pressure is generated by the pump assembly.

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.