The technology relates to autonomous vehicles having hitched or towed trailers for transporting cargo and other items between locations. Aspects of the technology provide a smart hitch connection between the fifth-wheel of a tractor unit and the kingpin of a trailer. This avoids requiring a person to make physical pneumatic and electrical connections between the fifth-wheel and kingpin using external hoses and cables. Instead, the necessary connections are made internally, autonomously. For instance, the fifth-wheel may provide air pressure via one or more slots arranged on a connection surface, and the trailer is configured to receive the air pressure through one or more openings on a contact surface of the kingpin. An electrical connection section of the fifth-wheel may also provide electrical signals and/or power to an electrical contact interface of the kingpin. Rotational information about relative alignment of the trailer to the tractor unit may also be provided.

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.

The present invention concerns systems, a kit and methods for monitoring coupling of a vehicle and a trailer or a trailer and another trailer. The system includes two sensors associated with a turntable of a towing vehicle, said sensors consisting of: a contact sensor configured to detect when a skid plate of a vehicle to be towed is in contact with the turntable; and a locking sensor configured to detect when the locking mechanism is in a locked configuration. The system further including a controller operatively connected to the two sensors and configured to receive output signals from the contact sensor and the locking sensor and to determine whether safe coupling has been achieved based on the output signals.

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).

A system and method for steering a trailer include the trailer being coupled to a fifth wheel of a motor vehicle. A trailer steering system for the motor vehicle includes a sliding rail mounted on a vehicle frame of the motor vehicle and extending along a lateral direction of the motor vehicle, a slider slidingly arranged on the sliding rail and carrying the fifth wheel for coupling the trailer to the motor vehicle, and a control device configured to control movement of the slider along the sliding rail depending on a current steering angle of the motor vehicle.

A coupling system for a fifth wheel coupling includes a first plug unit having a plurality of first plug connectors, and a second plug unit having a plurality of second plug connectors to engage and transmit power and/or fluid with the first plug connectors, and an adjuster unit having a guide section configured to be brought into engagement with a retaining element on one of the plug units to transmit a force from the adjuster unit to the plug unit, which displaces the plug unit along a plug-in axis, wherein the adjuster unit can be displaced transversely and laterally to the plug-in axis or can be rotated about the plug-in axis.

A gladhand coupler assembly is configured to releasably couple to a gladhand coupler having a mating seal and first and second mating structures. The gladhand coupler assembly includes an assembly mating seal for interfacing with the gladhand coupler mating seal and first and second assembly mating structures coupled to the assembly mating seal. The first and second assembly mating structures are configured to interface with the gladhand coupler first and second mating structures, respectively. The gladhand coupler assembly further includes an actuation mechanism configured to move the assembly mating seal relative to the pair of rigidly fixed assembly mating structures. The gladhand actuation mechanism is further configured to place the assembly mating seal into and out of fluid communication with the gladhand coupler mating seal.

An autonomous dock system for a vehicle, comprises a control system with instructions comprising steps for receiving a request to implement an autonomous dock routine. A vehicle speed and clutch position are calculated. A clutch position controller is commanded to maintain the calculated clutch position. An actual torque amount is iteratively detected as transferred across the clutch. A vehicle speed-control mechanism is commanded to maintain the calculated vehicle speed, and the actual vehicle speed is iteratively detected. When comparing the commanded vehicle speed to the detected actual vehicle speed indicates that the detected actual vehicle speed is below a speed threshold, and when the actual torque amount transferred across the clutch exceeds a torque threshold, the control system commands an increase in vehicle speed.

A system for assisting in aligning a vehicle for hitching with a trailer includes a first camera and a second camera and outputting image data to the rear of the vehicle and a controller identifying at least one of the trailer or a coupling feature of the trailer within the image data and assigning a trailer type to the trailer identified within the image data, the trailer type including a first trailer type and a second trailer type. The controller further causes a portion of the image data to be presented on a display within the vehicle, the portion of the image data corresponding with the first camera in response to the trailer being assigned the first trailer type and corresponding with the second camera in response to the trailer being assigned the second trailer type.

The vehicle system can include: a set of vehicle couplings (e.g., a tractor interface, a trailer interface, etc.); a chassis, a battery pack, an electric powertrain, a sensor suite, and a controller. The modular vehicle system can optionally include landing gear, a suspension, and any other suitable set of components. The vehicle system functions to structurally support and/or tow a trailer—such as a Class 8 semi-trailer—and/or to augment/supplement a tractor propulsive capability (e.g., via a diesel/combustion engine) with a supplementary electric drive axle(s).