A fifth wheel release arrangement for releasing a trailer from a towing vehicle in response to a trigger signal. The arrangement comprises one or more externally threaded fasteners and one or more pinion nuts comprising internal threads for engaging the external threads on the threaded fasteners, thereby holding the fifth wheel in position with respect to a first bracket attached to a towing vehicle frame, wherein the externally threaded fasteners are arranged to be rotationally fixed when received by the pinion nuts. The pinion nuts further comprise external teeth for engaging a toothed rack, and the rack is movable by an actuator system, in response to the trigger signal, in a direction to rotate the pinion nuts, whereby the externally threaded fasteners are ejected from the pinion nuts upon moving the rack by the actuator system in the direction, thereby releasing the trailer from the towing vehicle.

A fifth wheel mounting bracket includes a mounting bracket including a coupling portion configured to pivotally couple to a fifth wheel hitch plate, the mounting bracket including an innermost surface and an outermost surface defining a mounting bracket thickness, at least one isolation area having isolation area thickness that is less than the mounting bracket thickness, and at least one strain gauge positioned within the at least one isolation area and configured to measure a strain of the fifth wheel mounting bracket arrangement.

A fifth wheel control arrangement (100) for an articulated vehicle comprising a fifth wheel having a biased hinge joint and an actuator (115) arranged to control a biasing force and/or a damping force of the biased hinge joint. The control arrangement comprises a control unit configured to automatically control the actuator in response to one or more input sensor signals associated with a current state of the articulated vehicle, to obtain a target wheel axle load of the articulated vehicle and/or to stabilize the articulated vehicle.

An adjustable trailer hitch and king pin assembly that may be moved longitudinally to adjust the position and weight distribution of a trailer relative to a truck. The disclosed assembly may allow a trailer to be utilized with various different sized and configured trucks while maximizing the cargo carrying capability and efficiency thereof. In one example, an adjustable trailer hitch is provided having a slidable king pin assembly that may be adjusted forwards or backwards to move the king pin to the desired location relative to the truck and trailer. In another example, a removable king pin may be provided that may be removed and moved to a different location according to the weight and desired weight distribution of a truck and trailer combination.

A single point hitch bed system includes a base frame mounted on a truck bed, the base frame having a front end positioned towards the front of the truck, a rear end opposite the front end, and lateral side ends; a stationary upper deck permanently attached above the base frame; and an extendable lower deck positioned between the stationary upper deck and base frame, wherein the extendable lower deck is mounted via a rail system that allows the extendable lower deck to be extended to an adjustable length. An access hole is positioned towards the front of the stationary upper deck to allow access to a single point hitch that may be permanently secured to the truck. The single point hitch may receive removable components for securing cargo or towed apparatus to the truck. Auxiliary anchor points are positioned atop the base frame, laterally to the stationary upper deck.

A fifth wheel coupling including a coupling plate and a camera, wherein the coupling plate is supported on a towing vehicle by bearing elements, a centrally arranged locking region for receiving a king pin, a support surface at least partially laterally surrounding the locking region for supporting a trailer, as well as an insertion opening running radially from the locking region, which is bordered in a conically widened section on both sides by insertion flanges. The camera is mounted in a position in the region of the fifth wheel coupling with the lowest possible risk of soiling and damage, with the camera being arranged on one of the insertion flanges.

The present disclosure relates generally to a fifth wheel hitch and, more particularly, to a fifth wheel hitch having a latching system that is viewable to a user. In another instance, the present disclosure relates to a fifth wheel hitch having a latching system that permits a user to restrict movement of the fifth wheel hitch in at least two different planes of motion.

A remotely-engaging handle for a fifth wheel hitch system is provided. The remotely-engaging handle may comprise a body and a latching assembly that may be securely attached to the body and capable of engaging with a fifth wheel hitch. The latching assembly may comprise a locking member and an actuating member. The actuation of the actuating member may position a portion of the locking member from an unlocked position to a locked position. The locking member may comprise a latching arm rotating about a pivot point and a biasing member operatively attached the body. The biasing member may bias the locking member into a transitory position. In one embodiment, the actuating member may further comprise an electrically-operated button or a software-based interface. In particular embodiment, the locking member may further actuated by a solenoid and the connecting member may further comprise a wireless device.

A cast load cell comprising a load sensing portion integrally cast with a first mounting portion. The load sensing portion has a flexure portion spaced apart from the first mounting portion by a flexure gap. The load sensing portion has at least one sensor cavity above at least a portion of the flexure gap. A second mounting portion is integrally cast with the load sensing portion above the flexure gap. A load sensor is connected to the load sensor portion and positioned within the sensor cavity above a portion of the flexure gap. The first mounting portion, the load sensing portion, and the second mounting portion define an integral, low-profile, weld-free, substantially homogenous unitary cast member.