An elevated delivery platform having a delivery surface that can be placed at a location off the ground to better facilitate delivery of parcels by unmanned aerial vehicles, such as delivery drones, is provided. By placing the elevated delivery platform in an area above the ground, such as atop a home or a pole, a drone is more capable of making deliveries because it avoids obstacles nearer to the ground that typically make drone delivery challenging. The elevated delivery platform raises and lowers parcels to a position where they can easily be retrieved. Some systems also provide a deployable cover to protect parcels from adverse weather conditions while awaiting pickup or following delivery. The elevated delivery platform can be used as part of a drone delivery system that can also include a containment unit, a computer application, or any combination of these aspects.

The present disclosure provides an end-to-end cargo handling system. The end-to-end cargo handling system comprises a transportation unit comprising a first sensing agent, a lift unit comprising a second sensing agent, and a control module in communication with the transportation unit and the lift unit via a network, wherein the transportation unit and the lift unit are configured to move a cargo unit from a first location to a second location autonomously.

The present disclosure provides an end-to-end cargo handling system. The end-to-end cargo handling system comprises a transportation unit comprising a first sensing agent, a lift unit comprising a second sensing agent, and a control module in communication with the transportation unit and the lift unit via a network, wherein the transportation unit and the lift unit are configured to move a cargo unit from a first location to a second location autonomously.

Apparatus for loading or unloading a transport container provided with a load opening, including a telescopic conveyor, which has a main conveying unit and at least one telescopic conveying unit extendable relative thereto in a longitudinal direction, having a loading or unloading apparatus, which can be moved on a driving level and is coupled with the telescopic conveyor by means of a compensating device, the compensating device permitting a relative motion between the loading or unloading apparatus and the telescopic conveyor in respect to at least one degree of freedom.

Apparatus for loading or unloading a transport container provided with a load opening, including a telescopic conveyor, which has a main conveying unit and at least one telescopic conveying unit extendable relative thereto in a longitudinal direction, having a loading or unloading apparatus, which can be moved on a driving level and is coupled with the telescopic conveyor by means of a compensating device, the compensating device permitting a relative motion between the loading or unloading apparatus and the telescopic conveyor in respect to at least one degree of freedom.

In one embodiment, a mobile robot energizes its state-variable anchor into a released state while contacting a payload, and then de-energizes it to put it into an anchored state, attaching it to the payload. The mobile robot may then move the payload to a mounting location while the state-variable anchor is de-energized and attached to the payload. As such, the mobile robot may then energize a state-variable anchor of the payload to put it into a released state while at and contacting the mounting location, and then de-energizes it to put it into an anchored state to attach the payload to the mounting location. To then detach the state-variable anchor of the mobile robot and the mobile robot from the payload after the payload is attached to the mounting location, the mobile robot may then energize the state-variable anchor of the mobile robot to put it into a released state.

In one embodiment, a mobile robot energizes its state-variable anchor into a released state while contacting a payload, and then de-energizes it to put it into an anchored state, attaching it to the payload. The mobile robot may then move the payload to a mounting location while the state-variable anchor is de-energized and attached to the payload. As such, the mobile robot may then energize a state-variable anchor of the payload to put it into a released state while at and contacting the mounting location, and then de-energizes it to put it into an anchored state to attach the payload to the mounting location. To then detach the state-variable anchor of the mobile robot and the mobile robot from the payload after the payload is attached to the mounting location, the mobile robot may then energize the state-variable anchor of the mobile robot to put it into a released state.

Loading and unloading device configured for connection to a truck or a trailer of truck, having a main support frame, a support frame supported in a position adjustable by the main frame and a cradle supported in a position adjustable by the main frame and defining with it a goods storage compartment, and means for handling the secondary frame and the cradle with respect to the main frame along one or more directions of second axes X, Y, Z which are orthogonal to modify the configuration of the compartment.

A material-conveying system has a material-conveying apparatus for conveying material, an electronic control unit, a user interface control panel mounted to the apparatus and interfaced with the electronic control unit to receive user input commands to control the apparatus, a power unit mechanically coupled to the apparatus for powering the apparatus, a data bus communicatively connected between the power unit and the control unit, a portable remote control device for wirelessly transmitting command signals for remotely controlling a power output of the power unit to the apparatus, a wireless receiver at the apparatus for receiving the command signals from the portable remote control device and for transmitting the command signals to the electronic control unit that controls the power output of the power unit. The portable remote control device is also configured to wirelessly transmit a control signal to a gate controller of a material-unloading gate of a material container.

A robotic system is disclosed. The robotic system includes a robot. A module is coupled to the robot. An item is disposed within the module. The module includes a release door configured to be selectively opened and closed. When the release door is selectively opened, the item is dropped from the module.