Embodiments provide shelves, bracket systems, automated picker robots, totes, and other features that may be used with delivery vehicle configurations that have automated cargo areas. A delivery vehicle may include a picking robot that selectively retrieves packages for delivery without requiring substantial human intervention for locating those packages. The cargo area of the delivery vehicle may further comprise a plurality of customizable shelving units that generate custom-sized shelves for packages. The shelves may include a plurality of individually movable shelf brackets having retaining members that pivot between an extended and retracted position to hold the package in place and to enable the picking robot to retrieve the package from the shelf. Another embodiment provides for a tote having a drive mechanism to hold letters so that a letter may be automatically retrieved from the cargo arear and provided at a delivery location.

In one embodiment, a cable reel restraint device comprises a cable reel, a retractable cable, first and second springs, first and second attachment interfaces, and a preload selection control. The retractable cable is configured to extend from and retract onto the cable reel. The first spring is configured to exert force for preloading the second spring, and the second spring is configured to exert force for retracting the retractable cable. The first attachment interface is coupled to the cable reel by a first spherical bearing, and the second attachment interface is coupled to the retractable cable by a second spherical bearing. Moreover, the first and second attachment interfaces are configured for being fastened to first and second attachment points. The preload selection control is configured to select a particular preload magnitude and cause the first spring to preload the second spring with a load of the particular preload magnitude.

A cargo management system is provided. That cargo management system includes a mat of memory foam and at least one adjustable stop positioned below the mat and forming a raised hump in the mat to help retain cargo from shifting or rolling during motor vehicle operation. A method of managing cargo in a motor vehicle is also disclosed.

A wheelchair-dock system includes a floor including an elongated depression, a movable member, an actuator drivingly coupled to the member, and a position sensor coupled to the member. The depression defines a lateral direction. The member is movable in the lateral direction between an extended position over the depression and a retracted position.

A wheelchair-dock system includes a floor including an elongated depression, a movable member, an actuator drivingly coupled to the member, and a position sensor coupled to the member. The depression defines a lateral direction. The member is movable in the lateral direction between an extended position over the depression and a retracted position.

A cargo handling system for restraining a unit load device includes a structural channel having a hollow interior, and a locking mechanism associated with the structural channel. The locking mechanism is movable to engage the unit load device. A motor assembly is coupled to the at least one locking mechanism. The motor assembly is operable to automatically move the at least one locking mechanism upon detection of the unit load device at or approaching a desired position adjacent the at least one locking mechanism.

A removable chock for securing coolers, storage bins, and tool boxes on boats, and cargo areas of vehicles and trailers and the like. The low-profile base mounts to any flat surface, and allows the chock to be installed and uninstalled from the base without the use of any tools. The chock can be removed from the base when not being used and the base remains installed. The low-profile design of the base greatly reduces the potential trip hazard, as well as offers an aesthetically pleasing appearance than a permanently installed chock.

An autonomous traveling unit is provided with a pair of toggle mechanisms. The toggle mechanisms respectively have displaceable bodies provided with cam followers. A workpiece loading unit is provided with a member in an X shape to be clamped. The cam followers are respectively advanced to a pair of opposing corners (a first crossing portion and a second crossing portion) of the member to be clamped. When advancing to the pair of opposing corners, the cam followers are respectively brought into abutment on the member to be clamped, whereby the workpiece loading unit is restrained on the autonomous traveling unit.

A cargo management system for a cargo area at least partially defined between opposing sidewalls and a load floor of a vehicle includes at least one guide surface disposed proximate the load floor and a support structure adjustably connected to the at least one guide surface. The support structure includes a first post and a second post adjustable relative to the first post. A first translating member includes an upper portion pivotally connected to an upper end of the first post and a lower portion movably connected to a lower end of the second post. A second translating member includes an upper portion pivotally connected to an upper end of the second post and a lower portion movably connected to a lower end of the first post. The first and second translating members are adjustable between a first position and at least one second position.

A reversible load floor is provided for a motor vehicle. The reversible load floor includes a body having a first user surface and a second user surface wherein the first user surface is opposed to the second user surface.