An incentive-based waste reduction system and method thereof are disclosed herein. In accordance with one embodiment of the present invention, an incentive-based waste reduction system comprises a collection means comprising at least a load-determining device, the collection means for obtaining a quantifiable measure of waste material from an entity, a value associated with the quantifiable measure of waste material, an adjustment factor for adjusting the value associated with the quantifiable measure of waste material, determined from an algorithm, the algorithm taking as an input at least a predetermined factor, a credit value associated with at least a quantifiable measure of deposited waste material, and a reward value associated with the credit value. Information about the waste material is transmitted to a host server which performs actions based on the received information, including reconfiguring a deployment scheme of trucks to routes to save resources.

A system is disclosed for monitoring waste collected by a service vehicle. The system may include a lift actuator configured to cause lifting of the waste, a power takeoff driven by a powertrain of the service vehicle to power the lift actuator, and a sensor configured to generate a speed signal indicative of a speed of the powertrain. The system may also include an output device, and a controller in communication with the sensor and the output device. The controller may be configured to receive the speed signal from the sensor, determine an amount of waste lifted by the lift actuator based on the speed signal, and relay the amount of waste to the output device.

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.

A refuse collection drone includes a chassis, tractive elements rotatably coupled with and supporting the chassis, a propulsion system including a battery and an electric motor configured to consume electrical energy from the battery, and a bin removably coupled with the chassis and including a cover. The propulsion system is configured to drive one or more of the tractive elements to transport the refuse collection drone to a customer location. The bin defines a storage volume for refuse. The cover is configured to be driven by an actuator between an open position to allow access to the storage volume and a closed position to limit access to the storage volume. A lock is operable between a locked state to limit transition of the cover out of the closed position and an unlocked state to allow transition of the cover out of the closed position and into the open position.

A depot for autonomous land-based refuse drones includes a chassis anchored to a ground surface, a container defining a storage volume for refuse, a collection implement, and refuse actuators. The collection implement is configured to selectively couple with at least one of (i) refuse within a drone storage volume or (ii) a portion of the one of the autonomous land-based refuse drones that defines the drone storage volume. The refuse actuators are operably coupled with the collection implement and configured to drive the collection implement to perform an unloading operation. The unloading operation includes selectively coupling, moving, and de-coupling from at least one of the refuse within the drone storage volume or the portion of the autonomous land-based refuse drone that defines the drone storage volume to unload the refuse from the drone storage volume into the storage volume of the container.

A refuse collection includes one or more memory devices storing instructions thereon, that, when executed by one or more processors, cause the one or more processors to (a) receive a request for refuse collection from a customer, the request including a desired time of the refuse collection, (b) identify, based on the request, a location of a pickup zone associated with the customer, and (c) control, based on the request, the refuse collection robot to autonomously navigate to the location of the pickup zone at the desired time and perform the refuse collection.

A refuse collection system includes one or more memory devices storing instructions thereon, that, when executed by one or more processors, cause the one or more processors to (a) receive a request for refuse collection from a customer, (b) identify, based on the request, a location of a pickup zone associated with the customer, (c) receive location data indicating a current location of the refuse collection robot, (d) generate a route for the refuse collection robot to travel from the current location of the refuse collection robot to the location of the pickup zone, and (e) control the refuse collection robot to follow the route and perform the refuse collection.

A refuse collection system includes one or more memory devices storing instructions thereon, that, when executed by one or more processors, cause the one or more processors to (a) control a refuse collection robot containing a volume of refuse to navigate to a refuse depot, (b) control the refuse depot to remove the volume of refuse from the refuse collection robot, (c) receive a request from a customer for delivery of a package, (d) identify, based on the request, a location of a pickup zone associated with the customer, (e) control the refuse collection robot to receive the package, and (f) control the refuse collection robot to transport the package to the pickup zone.

A system is disclosed for monitoring waste collected by a service vehicle. The system may include a lift actuator configured to cause lifting of the waste, a power takeoff driven by a powertrain of the service vehicle to power the lift actuator, and a sensor configured to generate a speed signal indicative of a speed of the powertrain. The system may also include an output device, and a controller in communication with the sensor and the output device. The controller may be configured to receive the speed signal from the sensor, determine an amount of waste lifted by the lift actuator based on the speed signal, and relay the amount of waste to the output device.

A weight based load limiting system for a refuse vehicle. The system includes a weight determination module that generates a signal that varies in accordance with a vehicle weight. If the vehicle weight approaches or exceeds a predetermined maximum weight, the signal inhibits a portion of the loading or packing operation to prevent overloading the vehicle. In various configurations, the inhibiting can be to prevent a lifting of a refuse container to prevent emptying the container into the vehicle hopper. In other various configurations, the inhibiting occurs by maintaining engine power to less than the engine power typically output during a packing operation.