An apparatus and method for a mobile transport for delivering temperature-controlled contents includes a plurality of compartments coupled to a vehicle body where each compartment includes an interior space and a front panel defining a wall of the interior space. Each front panel is operable to open and reveal the interior space of its compartment in response to a predetermined condition. A temperature controller is configured to individually control a temperature setting within at least one of the plurality of compartments, and a germicidal controller is configured to provide a germicide to the interior space of each of the plurality of compartments. In operation, the mobile transport receives an order signal to pick up an item from a source, the order signal including the pickup location information, customer identification information, and delivery location information. After the item has been placed in the interior space of a compartment, the temperature controller sets the temperature setting for that compartment according to a type of the item. After arriving at the delivery location, the front panel of the compartment is opened in response to receiving an open request signal satisfying the predetermined condition, the open request signal including information relating to the customer identification information.

The present disclosure relates in general to carriers intended to be utilized with towing vehicles, and more specifically, to a wheeled carrier and method of use for providing additional cargo space while being towed behind an automobile or all-terrain vehicle. One aspect of the present disclosure is to provide a variety of removable and interchangeable body styles each designed to be utilized with different types of cargo (e.g., luggage, bikes, small animals) such that the carrier may support a wide range of uses depending on certain preferences of the consumer. Another aspect of the present disclosure is providing a wheeled carrier that is rigidly and removably coupled to the chassis of the towing vehicle at multiple positions without requiring a ball hitch, pivoting pin box, or sliding hitch. Rigidly coupling the carrier directly to the chassis of the towing vehicle at multiple positions significantly improves stability and safety while towing as compared to traditional trailers that are pivotably coupled at a single location. The carrier and method of use of the present disclosure is designed to be utilized with smaller, more fuel-efficient towing vehicles to offer additional cargo storage space. Moreover, the carrier and method of use allows the carrier to be decoupled from the towing vehicle to lessen the impact on overall fuel economy and range mileage for the towing vehicle when the carrier is not being used.

Methods perform one or more dispatched medical logistics operations using a modular autonomous bot apparatus assembly and a dispatch server where the operations are related to a diagnosis kit for treating a patient. The MAM of the bot receives a dispatch command, verifies compatibility of the bot assembly with the dispatched operation(s), receives a diagnosis kit in the CSS, has the MAM autonomously causing the MB to move to a destination location while notifying the authorized delivery recipient for the diagnosis kit of the approaching delivery. With appropriate authentication input received, the MAM coordinates with the CSS to provide access to the kit, monitor unloading of the kit, provide instructional information on use of the kit, and autonomously cause the MB to return to the original location with a return item related to the diagnosis kit with notification to personnel at the medical entity about the return item.

The disclosure is generally directed to systems and methods for a reconfigurable on-board package sorting system for a delivery vehicle including an enclosed storage compartment with a horizontal plane, a plurality of bins for holding packages, each bin including a computer readable identifier, a set of correlated conveyor belts on each horizontal plane, the correlated conveyors belts sized as a function of the bins, including at conveyor belts linearly oriented on the horizontal plane, mixing conveyors, each oriented adjacent to each convey belt to provide directional transition to a next conveyor belt, wherein the correlated conveyor belts provide directional movement of the bins in a loop on the horizontal plane by selective rotation of each conveyor belt, and a computer including a processor and memory to receive data from each identifier, the processor including instructions to: identify a location of bin and direct the operation of the correlated conveyor belts.

A recovery system for recovering wrecked vehicles in difficult-to-access locations generally includes a frame, a front plate, a rear plate with a mounting system for mounting the recovery system to an operating vehicle, a guide shaft and guide wheel, a boom assembly, a horse head assembly mounted in a cable sleeve in a pivot end of the boom assembly, a winch, and a cable running from the winch over and along the boom and through the horse head assembly. The horse head assembly generally includes a clevis, a clevis pin, a sheave wheel, and a cable guide. The clevis preferably rotates within the cable sleeve with respect to the boom assembly, the cable guide preferably pivots on top of the boom assembly, and the sheave wheel and cable guide preferably freely rotate on the clevis pin and preferably translate along the clevis pin.

A vehicle includes a chassis and a vehicle body coupled to the chassis. The vehicle body includes a cab disposed on a forward end of the chassis and a cargo body disposed on a rear end of the chassis. The cab includes a front door that is slidably engaged to the cab. The cargo body includes a side door that is slidably engaged to the cargo body. The front door and the side door are disposed on the same side of the vehicle.

A vehicle includes a chassis, a cargo body coupled to the chassis, a cargo support member, and a shelf assembly. The cargo support member is mounted to an outer wall of the cargo body and is disposed within the cargo body. The shelf assembly includes a tray and a strap. The tray is hingedly coupled to the cargo support member. The strap is coupled to the tray and the cargo support member. The strap is adjustable to reposition a forward end of the tray.

A modular robot system which may be configured to accommodate packages of varying sizes is provided. The modular robot may include a base having omni-directional wheels and cameras and sensors, one or more modular containers, and a lid, which may be releasably linked together to form a small, medium or larger units. The base may include a lifting mechanism to vertically raise the robot to a desired height in alignment with a delivery vehicle. Moreover, retractable loading arms of the vehicle may be extended from the vehicle to engage with the robot to facilitate self-loading of the robot into the delivery vehicle.

Package sorting systems and methods of use are disclosed herein. An example system includes a platform of a vehicle, where the platform is arranged as a grid having a plurality of slots (including an open slot and a target slot). A plurality of slabs can be placed into the grid except for in the open slot. A slab moving assembly is used to move the slabs in order to place a selected slab into the target slot on the platform.

A bridge detecting vehicle with two foldable arms, including: a vehicle body, slewing mechanisms, horizontal and vertical arms and telescopic arms. One end of the two horizontal arms is respectively arranged on the slewing mechanisms, and the other end of the two horizontal arms is respectively connected to the two horizontal arms. A crossed arm is provided between the two horizontal arms. The two vertical arms are respectively connected to the two horizontal arms via ball joints. A detecting device is respectively provided at rear ends of the two telescopic arms.