A movable car seat movably connected to a conventional car seat backrest, the movable car seat including a main body to allow a person to sit thereupon, a telescopic pole disposed laterally within the main body to extend to allow the main body to move laterally with respect to the conventional car seat backrest, and a tilting system to allow the main body to move from a horizontal position to an angled position when the telescopic pole is extended.

A garbage bin carting system for securing and transporting a garbage bin includes a cart that moves over a ground surface. The cart is motorized and remotely controlled. A saddle is mounted on top of the cart. The saddle releasably secures a garbage bin to the cart such that the garbage bin is transportable by the cart.

A refuse collection system includes a refuse collection robot and a refuse depot. The refuse collection robot includes a chassis, a tractive element coupled to the chassis, a motor coupled to the chassis and the tractive element and configured to drive the tractive element to propel the refuse collection robot, a refuse container coupled to the chassis and defining a first storage volume, and a controller operatively coupled to the motor. The refuse depot includes a centralized storage defining a second storage volume and a refuse actuator configured to transfer refuse from the first storage volume to the second storage volume. The controller is configured to control the motor to propel the refuse collection to a pickup zone associated with a customer in response to receiving a request for refuse collection from a user device associated with the customer.

Embodiments disclosed herein provide a user experience to interact with an organic matter processing apparatus (OMPA) that converts organic matter into a ground and dried shelf-stable product. The user experience can be accessed via an application that operates on a mobile device or a website. The application can be used to set an operational schedule of the OMPA, start or stop an OMPA processing cycle, observe a status of the OMPA, observe statistics related to the OMPA, request supplies, access a guide to assess whether certain organic matter can be safely added to the OMPA, and alert the user of potential issues with the OMPA.

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.

A non-transitory computer-readable media comprising computer-readable instructions stored thereon that, when executed by a processor, causes the processor to generate a route, control a drone to surveil an area along the route, generate, from a sensor on the drone, status data for one or more refuse containers, analyze the status data to determine a status of refuse within the area, provide a notification to a customer based on the status of refuse, repeat surveillance to determine if the status of refuse has changed, generate a revised route in response to determining that the status of refuse has changed, and update a customer bill in response to determining that the status of refuse has changed.

A system is disclosed for autonomously removing waste from a plurality of receptacles at separate locations within a service area. The system may include a service vehicle, and a plurality of transporters. The plurality of transporters may be configured to autonomously move the plurality of receptacles to the service vehicle.

A system is disclosed for autonomously removing waste from a plurality of receptacles at separate locations within a service area. The system may include a service vehicle, and a plurality of transporters. The plurality of transporters may be configured to autonomously move the plurality of receptacles to the service vehicle.

Provided is a robotic refuse container, including a chassis; a set of wheels coupled to the chassis; a refuse container coupled to the chassis for collecting refuse; a rechargeable battery; a plurality of sensors; a processor; and a tangible, non-transitory, machine-readable medium storing instructions that when executed by the processor effectuates operations including: detecting, with at least one sensor disposed on the robotic refuse container, an amount of refuse within the refuse container; instructing, with the processor, the robotic refuse container to navigate to a location to empty the refuse upon detecting the amount of refuse exceeds a predetermined refuse amount in the refuse container; and emptying, by a separate device, the refuse within the refuse container at the location.

A trash container having an automated trash bag dispensing system which automatically deploys a replacement trash bag upon removal of a filled bag. A supply of trash bags is fed into the main trash container by a motorized roller assembly. A pair of opposing suction pads are pivotally deployed inward and suction activation attracts the opposing sides of the bag to corresponding suction pads. Retraction of the suction pads functions to expand the bag to an open configuration whereby it is suitably configured to receive trash.