A delivery vehicle is configured to be able to deliver a package in front of a front door of a dwelling unit in a complex housing including a shared door with automatic lock function that is able to be opened as unlock information is input to an unlock input unit of an entrance via wireless communication. When the delivery vehicle arrives at the complex housing including the shared door with automatic lock function, and a delivery instruction for leaving the package in front of the front door is made, an on-board unit of the delivery vehicle inputs the unlock information to the unlock input unit via the wireless communication, and notifies a terminal device of a user of input date and time.

Systems and methods for automated security inspection and routing of in-transit objects are described. In one embodiment, a plurality of security screening devices are provided, each operable to output screening data of an in-transit object, including a first screening device located in a sealed environment of a vehicle for transporting the object towards a conveying system, including one or more measuring devices operable to measure screening parameters of the object when located in the sealed environment, and a second screening device in combination with conveying and routing components of the conveying system used to transport said objects from an ingress point through a conveyor junction to reach the second screening device. A control unit is assigned to the conveyor junction, wherein the control unit is configured to receive security data assigned on the basis of the screening data from the first screening device to the object upstream of the conveyor junction, and in response, to determine and set a routing direction on the basis of the assigned security data, whereby the object is directed downstream to a screening route for further screening by the second screening device, or to a loading route for objects cleared for loading. Other embodiments are also described and claimed.

Systems and methods for automated security inspection and routing of in-transit objects are described. In one embodiment, a plurality of security screening devices are provided, each operable to output screening data of an in-transit object, including a first screening device located in a sealed environment of a vehicle for transporting the object towards a conveying system, including one or more measuring devices operable to measure screening parameters of the object when located in the sealed environment, and a second screening device in combination with conveying and routing components of the conveying system used to transport said objects from an ingress point through a conveyor junction to reach the second screening device. A control unit is assigned to the conveyor junction, wherein the control unit is configured to receive security data assigned on the basis of the screening data from the first screening device to the object upstream of the conveyor junction, and in response, to determine and set a routing direction on the basis of the assigned security data, whereby the object is directed downstream to a screening route for further screening by the second screening device, or to a loading route for objects cleared for loading. Other embodiments are also described and claimed.

A delivery robot equipped with a loading module is disclosed. The delivery robot includes a communicator for communicating with a control center or a mobile terminal within a control range of an article sender, one or more sensing units, an inputter for receiving information on an article and destination information on the article, a memory for storing a delivery list, a display, and a controller. The delivery robot may be equipped with artificial intelligence and may also perform 5G (generation) communication. Thus, user convenience can be improved.

Various embodiments provide a vehicle wheel chock hanger for holding different vehicle wheel chocks of different vehicle restraint systems. Various embodiments provide a vehicle wheel chock hanger for vehicle restraint systems for a vehicle such as an auto-rack railroad car that is configured to hold various different chocks that are configured to secure vehicles in that vehicle.

A rail can include first and transverse channels defined therein. A container can include a rod, a spring, a first plate assembly, and a second plate assembly. The first plate assembly can include a first transverse bearing disposed in the first transverse channel. The second plate assembly can include a second transverse bearing disposed in the second transverse channel. A robotic assembly can include a robotic arm. The robotic arm can include opposing grips defining a grip space therebetween. A processing system including one or more processors can be configured to, via the robotic assembly: align the grip space with the container rod; drive the rod against the spring; allow the spring to relax and thereby separate the first plate assembly from the second plate assembly; position the rod such that the first transverse bearing and the second transverse bearing are simultaneously withdrawn from the first and second transverse channels.

A rail can include an entry portion, an exit portion, and a middle portion disposed between the entry and exit portions. The middle portion can be lower than the entry and exit portions. The rail can be configured to couple with a container such that the container is movable, along the rail, from the entry portion to the exit portion. A first storage rack can be disposed on a first side of the rail middle portion and a second storage rack can be disposed on an opposing side of the rail middle portion. A processing system can be configured to: receive an order; analyze the order based on an inventory of the first storage rack and the second storage rack; and cause the container to move from the rail entry portion to the rail middle portion based on the analysis.

An autonomous robotic vehicle includes a conveyance system, a securable compartment configured to autonomously lock and unlock, a customer identification reader, at least one processor, and a memory storing instructions which, when executed by the at least one processor, causes the autonomous robotic vehicle to, autonomously: travel to a destination location of a customer; capture, by the customer identification reader at the destination location, a customer identification object; determine that the captured customer identification object matches an identity of the customer; unlock the securable compartment based on the determination; capture, by the product identification reader, a product identifier; and accept a product to be returned by locking the securable compartment. The securable compartment contains a product identification reader.

A mobile work system and methods for operationally receiving a work performing and/or energy delivering attachment. A work platform is powered by a power output device and includes a source of electricity for powering the attachment. The platform has a first end and a second end generally opposite the first end. A first attachment interface is connected to the first end, and a second attachment interface, substantially operationally equivalent to the first attachment interface, is connected to the second end. The first end of the platform also includes a first steering mechanism, and the second end includes a second steering mechanism substantially operationally equivalent to the first steering mechanism, whereby the platform is configured to be propelled and steered in a first direction and propelled and steered in a second direction generally opposite the first direction by the first and second steering mechanisms, respectively.

A land vehicle includes a frame structure, a plurality of wheels supported by the frame structure, and a body supported by the frame structure. The frame structure includes an operator cage that at least partially defines an operator cabin and a rear compartment positioned rearward of the operator cage in a longitudinal direction. The body includes a first sidewall arranged on one side of the vehicle and a second sidewall arranged on another side of the vehicle opposite the first sidewall.