A system according to the present disclosure includes a trailer distance module, a trailer contact module, a trailer distance module, and at least one of a driver warning module, a brake control module, and a steering control module. The trailer distance module determines a distance from a cab of a truck to a fifth wheel trailer attached to the truck based on an input from a sensor. The trailer contact module identifies potential contact between the trailer and the truck cab based on the cab-to-trailer distance. The driver warning module warns a driver of the potential contact. The brake control module applies a brake of at least one of the truck and the trailer when potential contact is identified. The steering control module increases an amount of driver effort required to steer the truck in at least one direction when potential contact is identified.

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.

Techniques are described for measuring angle and/or orientation of a rear drivable section (e.g., a trailer unit of a semi-trailer truck) relative to a front drivable section (e.g., a tractor unit of the semi-trailer truck) using an example rotary encoder assembly. The example rotary encoder assembly comprises a base surface; a housing that includes a second end that is connected to the base surface and a first end that is at least partially open and is coupled to a housing cap; and a rotary encoder that is located in the housing in between the base surface and the housing cap, where the rotary encoder includes a rotatable shaft that protrudes from a first hole located in the housing cap, and where a top of the rotatable shaft located away from the rotary encoder is coupled to magnet(s).

Embodiments of the present disclosure include methods, apparatuses, and systems for receiving feedback during transport. Embodiments include a transportation system comprising a tractor, a dolly attached to opposing ends of a first and second trailer, and a sensor feedback system. Sensor feedback system may include a tilt sensor system mounted on at least one of the dolly, the first trailer, and the second trailer, and a user feedback system mounted within the tractor. Tilt sensor system may measure tilt of at least one of the dolly, first and second trailers, and first and second containers attached to the first and second trailers, to obtain tilt information, and send tilt information to the user feedback system via a communication system. User feedback system may receive the tilt information and alert a driver of the tractor if the tilt information is above a predetermined level.

A rollover prevention architecture for a vehicle comprising a reactive force member mounted on the vehicle, the reactive force member controlled to generate a counter torque relative to the direction of sensed tipping or rollover to mitigate the tipping or rollover of the vehicle while the vehicle is moving.

According to an embodiment, the width of the upper surface base of an uniaxial coupler (including the case where a biaxial type is used as uniaxial) normally installed in a tractor is formed to be extended in a lateral direction to an arbitrary length ranged from 1.5 times of the conventional coupler to substantially a full width of the vehicle.

The disclosure is directed at an apparatus, method and computer readable medium for a self-powered towed vehicle in a road train or tractor-trailer vehicle configuration to detect and respond to forward jack-knifing risk conditions. The apparatus may detect jack-knifing risk conditions based on sensors and information including sensors to detect an angle of misalignment between the towed vehicle and the vehicle directly in front of it in the road train. The apparatus may respond to the presence of a jack-knifing risk condition by reducing or eliminating the motive rotational force applied to the wheels of the towed vehicle.

A terminal tractor, comprising: (a) an operator cab, (b) a fifth wheel configured for repositioning trailers, and (c) a trailer stabilizer lift separate from the fifth wheel.

A method for controlling steering of a self-powered steerable dolly vehicle during a maneuver, the method comprising determining an articulation angle associated with a drawbar of the dolly vehicle, determining a longitudinal velocity of the dolly vehicle, and controlling the steering of the dolly vehicle based on the articulation angle and on the longitudinal velocity of the dolly vehicle, wherein the controlling comprises initially steering the dolly vehicle in a direction of the articulation angle direction in case the longitudinal velocity of the dolly vehicle is above a velocity threshold.

The disclosure is directed at an apparatus, method and computer readable medium for a self-powered towed vehicle in a road train or tractor-trailer vehicle configuration to detect and respond to forward jack-knifing risk conditions. The apparatus may detect jack-knifing risk conditions based on sensors and information including sensors to detect an angle of misalignment between the towed vehicle and the vehicle directly in front of it in the road train. The apparatus may respond to the presence of a jack-knifing risk condition by reducing or eliminating the motive rotational force applied to the wheels of the towed vehicle.