An apparatus and method are provided for determining the braking status of trailers and dollies in a multi-trailer vehicle train. A vehicle controller receives inputs from the vehicle to determine an estimate of the total vehicle mass from the dynamic response of the vehicle to an input such as application of engine torque, and to determine an estimate of the loads of the vehicle based on information provided from trailers and dollies communicating with the vehicle controller. A plausibility analysis is conducted to determine whether the estimates are within a tolerance range indicative of whether all of the trailers and dollies are communicating with the vehicle controller. If the vehicle controller determines that not all of the trailer and dolly anti-lock braking and/or stability control systems are available, the vehicle controller may in subsequent braking events command trailer and dolly brake application at a reduced level intended to avoid trailer and dolly wheel skidding.

A trailer brake system that generates load-dependent braking forces. Variable trailer load information is used to generate load-dependent control signals which serve to control an electrically-controlled proportional valve. A load sensing valve serves to modify brake command signals in dependence on a control pressure that is regulated by the proportional valve.

A trailer brake system that generates load-dependent braking forces. Variable trailer load information is used to generate load-dependent control signals which serve to control an electrically-controlled proportional valve. A load sensing valve serves to modify brake command signals in dependence on a control pressure that is regulated by the proportional valve.

The present disclosure relates to an apparatus for controlling a braking force of a platooning vehicle. The apparatus includes a braking distance predicting unit configured to predict a predicted braking distance of a host vehicle, a braking restriction determining unit configured to determine whether a braking distance of the host vehicle is to be restricted, by comparing the predicted braking distance of the host vehicle with predicted braking distances of following vehicles. The apparatus further includes a braking restriction degree determining unit configured to determine a braking restriction degree of the braking distance of the host vehicle in the case in which it is necessary to restrict the braking distance of the host vehicle.

The present disclosure relates to an apparatus for controlling a braking force of a platooning vehicle. The apparatus includes a braking distance predicting unit configured to predict a predicted braking distance of a host vehicle, a braking restriction determining unit configured to determine whether a braking distance of the host vehicle is to be restricted, by comparing the predicted braking distance of the host vehicle with predicted braking distances of following vehicles. The apparatus further includes a braking restriction degree determining unit configured to determine a braking restriction degree of the braking distance of the host vehicle in the case in which it is necessary to restrict the braking distance of the host vehicle.

A vehicle weight sensing system particularly useful for trailers. An axle tube is mounted to the vehicle or trailer through its suspension members that may be leaf springs. A mounting block is affixed to the axle tube for mounting a strain gauge. The mounting block is fixed to the axle tube between the suspension members connected to the axle tube. The mounting block has a mounting surface opposite to the mating surface and a notch extends from the mating surface toward the mounting surface. The notch terminates between the mating surface and the mounting surface. The notch separates rigidified sections of the mounting block and the rigidified sections straddle the notch. The stain gauge measures strain in the axle and thereby generates a signal proportional to the weight on the trailer. The signal can be used to properly proportion a brake system on the trailer.

A remote stop system for a vehicle configured to be operated autonomously or semi-autonomously. The remote stop system includes a mechanical remote stop system configured to apply a first braking force and an electrical remote stop system configured to apply a second braking force. A remote stop actuator is configured to send a wireless control signal to the vehicle. The remote stop actuator having two states: a first state having the remote stop actuator transmitting the wireless control signal to the mechanical remote stop system and the electrical remote stop system and a second state having the remote stop actuator without transmitting the wireless control signal to the mechanical remote stop system and the electrical remote stop system. In the second state, the first braking force and the second braking force are applied simultaneously. A vehicle system includes the vehicle and the remote stop system.

A pressure sensing system of a pneumatic spring brake chamber for a vehicle according to an embodiment of the present disclosure includes a plurality of pressure sensors configured to measure pressure in a pressure chamber formed between a piston and an adapter housing and a service chamber formed between the adapter housing and a diaphragm, a control box electrically connected to the plurality of pressure sensors, and an indicator electrically coupled to the control box, wherein the control box is wired for power supply and output voltage to the plurality of pressure sensors, and the indicator located in a vehicle driver's seat is configured to generate an alarm about an abnormal situation of the pneumatic spring brake chamber for a vehicle based on pressure measurement values in the pressure chamber and the service chamber through the plurality of pressure sensors.

A pouch type secondary battery according to the present invention includes: an electrode assembly; a battery case accommodating the electrode assembly in an inside thereof; an electrode tab protruding from the electrode assembly; a first electrode lead having an inner end connected to the electrode tab; a second electrode lead having an inner end coupled to an outer end of the first electrode lead and an outer end extending outside of the battery case; a connection part coupling the first and second electrode leads to each other; an insulation part fused around a portion of each of the first and second electrode leads, the insulation part bonding the first and second electrode leads to the battery case; and a fusion prevention part located at a position at one surface of the first electrode lead, the fusion prevention part preventing the first electrode lead from being fused to the insulation part.

An apparatus and method are provided for determining the braking status of trailers and dollies in a multi-trailer vehicle train. A vehicle controller receives inputs from the vehicle to determine an estimate of the total vehicle mass from the dynamic response of the vehicle to an input such as application of engine torque, and to determine an estimate of the loads of the vehicle based on information provided from trailers and dollies communicating with the vehicle controller. A plausibility analysis is conducted to determine whether the estimates are within a tolerance range indicative of whether all of the trailers and dollies are communicating with the vehicle controller. If the vehicle controller determines that not all of the trailer and dolly anti-lock braking and/or stability control systems are available, the vehicle controller may in subsequent braking events command trailer and dolly brake application at a reduced level intended to avoid trailer and dolly wheel skidding.