A pin box assembly with gooseneck coupler for coupling a towed vehicle to a towing vehicle is described. The pin box assembly may include a first member capable of being secured to a towed vehicle and a second member pivotally coupled to the first member about an axis of rotation relative to the first member. The pin box assembly may further include a gooseneck ball coupler coupled to the second member, and a suspension system coupled to at least one of the first and second members, the suspension system damping motion between the first and second members.

A hitch mount configured to be selectively attached to a vehicle, the vehicle having an under bed hitch mounting system is shown and described. The hitch mount may include at least one transverse member, at least one longitudinal member attached with the at least one transverse member, the at least one longitudinal member including first and second apertures, the first and second apertures of different size, and first and second fastening devices configured to selectively engage the under bed hitch mounting system and the first and second apertures, respectively. The hitch mount may also include first and second biasing members operatively engaged with the first and second fastening, the biasing members applying a load against the under bed hitch mounting system, and first and second handles pivotally and rotatably attached with the first and second fastening devices, the handles having a camming surface configured to engage the first and second biasing members.

An underbed hitch mounting system is described. The mounting system may be utilized for towing vehicles wherein the mounting system may selectively accommodate either a fifth wheel hitch or a gooseneck hitch. The mounting system may include at least one rail capable of being connected to a vehicle frame, wherein the rail includes at least one socket. The socket may be engaged with a receiving member, wherein the receiving member may be engaged with a leg of a fifth wheel hitch. A mid rail may be connected to the rails and may include a hitch ball socket that is capable of engagement with a hitch.

An under bed hitch mounting apparatus is shown and described. The under bed hitch mounting apparatus may comprise a first bracket attachable to a frame of a vehicle below a load bed of the vehicle and a second bracket attachable to the frame of the vehicle below a load bed of the vehicle, the second bracket transversely spaced from the first bracket. The under bed hitch mounting apparatus may also include a first receiving member attached with the first bracket, the first receiving member configured to engage an accessory member, where at least a portion of the first receiving member extends above the load bed of the vehicle, and a second receiving member attached with the second bracket, the first receiving member configured to engage the accessory member, where at least a portion of the second receiving member extends above the load bed of the vehicle.

A coupling device for coupling a first vehicle to a second towed vehicle includes a pillar for mounting to a towbar of the first vehicle, the pillar defining a primary longitudinal axis and including an upper portion, a lower portion adapted for engagement with the towbar of the first vehicle, and an intermediate portion including a radially protruding locking flange, a coupling body adapted for sleeved engagement with the upper portion of the pillar, the coupling body including at least one locking device for locking the coupling body to the locking flange of the pillar, and a rotary cap operatively associated with the at least one locking device and adapted for rotation relative to the coupling body. Rotation of the rotary cap causes the locking device to pivot between at least a locked position and an unlocked position.

A coupling device for coupling a first vehicle to a second towed vehicle includes a pillar for mounting to a towbar of the first vehicle, the pillar defining a primary longitudinal axis and including an upper portion, a lower portion adapted for engagement with the towbar of the first vehicle, and an intermediate portion including a radially protruding locking flange, a coupling body adapted for sleeved engagement with the upper portion of the pillar, the coupling body including at least one locking device for locking the coupling body to the locking flange of the pillar, and a rotary cap operatively associated with the at least one locking device and adapted for rotation relative to the coupling body. Rotation of the rotary cap causes the locking device to pivot between at least a locked position and an unlocked position.

A system and method for operation of an autonomous vehicle (AV) yard truck is provided. A processor facilitates autonomous movement of the AV yard truck, and connection to and disconnection from trailers. A plurality of sensors are interconnected with the processor that sense terrain/objects and assist in automatically connecting/disconnecting trailers. A server, interconnected, wirelessly with the processor, that tracks movement of the truck around and determines locations for trailer connection and disconnection. A door station unlatches/opens rear doors of the trailer when adjacent thereto, securing them in an opened position via clamps, etc. The system computes a height of the trailer, and/or if landing gear of the trailer is on the ground and interoperates with the fifth wheel to change height, and whether docking is safe, allowing a user to take manual control, and optimum charge time(s). Reversing sensors/safety, automated chocking, and intermodal container organization are also provided.

Systems, methods, and apparatuses for engaging, lifting, and moving objects such as wheeled cargo trailers are provided. In one embodiment, a mobile apparatus includes a transport mechanism, a frame, and one or more lift assemblies. The lift assemblies may be adjusted using one or more attached actuators that position the lift assemblies and/or components thereof for engaging and lifting an object. The transport mechanism may be autonomously operated. A vision system may be used to locate and identify objects and/or guide the mobile apparatus into position to engage and lift the objects. An adapter for a pneumatic braking system of a wheeled cargo trailer is also provided. The adapter provides a pneumatic attachment for a pressurized air source that is separate from a glad hands connector attached to the braking system.

A king pin coupler assembly of a fifth wheel coupling. A coupler plate has a king pin aperture therein. A king pin is positioned to extend axially through the king pin aperture of the coupler plate. The king pin has a first portion with a neck for engaging a fifth wheel of the fifth wheel coupling, the first portion extending to a first side of the coupler plate. The king pin has a second portion on a second side of the coupler plate and welded to the coupler plate. A shielding apparatus is secured to one or both of the king pin and the coupler plate. The shielding apparatus includes a cover sealed to the first side of the coupler plate. The cover extends over the first portion of the king pin to shield the first portion of the king pin during liquid immersion of the king pin coupler assembly.

Methods, apparatus, systems and articles of manufacture are disclosed for a modular double pin load sensor coupled to a hitch receiver. An example disclosed apparatus to be coupled to a receiver tube includes a crossbar interface to be coupled to a crossbar of a hitch, a pin adapter coupled to the crossbar interface, a first load-sensing pin disposed within the pin adapter, and a second load-sensing pin disposed within the pin adapter.