A system and method include a train including a plurality of rail cars configured to travel along a track having rails. Each of the plurality of rail cars includes brakes. A braking control unit is in communication with the brakes of the plurality of rail cars. The braking control unit is configured to control the brakes of a subset of the plurality of rail cars in accordance with braking data.

A system and method include a train including a plurality of rail cars configured to travel along a track having rails. Each of the plurality of rail cars includes brakes. A braking control unit is in communication with the brakes of the plurality of rail cars. The braking control unit is configured to control the brakes of a subset of the plurality of rail cars in accordance with braking data.

A water ride including vehicles that ride on a track and using water for braking. A run-out section of the track is provided after a drop or down chute section, and the track in the run-out section runs through a pool of water at a depth causing at least a portion of a vehicle riding on the rails to contact a depth of the water to achieve vehicle braking. Significantly, the new water ride is adapted to adjust or set a variable height of the rails in the run-out chute or pool to adjust the depth of water providing water drag on a vehicle traveling through the run-out section based on the vehicle weight. A braking force is applied by the water that is proportional to vehicle weight, and the water ride may be thought of as slowing vehicles with a range of weights at about the same deceleration rate.

A water ride including vehicles that ride on a track and using water for braking. A run-out section of the track is provided after a drop or down chute section, and the track in the run-out section runs through a pool of water at a depth causing at least a portion of a vehicle riding on the rails to contact a depth of the water to achieve vehicle braking. Significantly, the new water ride is adapted to adjust or set a variable height of the rails in the run-out chute or pool to adjust the depth of water providing water drag on a vehicle traveling through the run-out section based on the vehicle weight. A braking force is applied by the water that is proportional to vehicle weight, and the water ride may be thought of as slowing vehicles with a range of weights at about the same deceleration rate.

A system and method for reducing the threat of derailment of a train during deceleration is provided. An individualized braking force for each rail car of a train, such individualized braking force being determined by the braking deceleration of the train's locomotive, may be calculated by the rail car's controller and is directly proportional to the mass of the rail car. The controller may utilize the various forces acting upon the individual rail car as measured by a plurality of sensing and measuring devices to dynamically adjust the braking force applied to the individual rail car's brakes. Such a system and method allows for the train to act as a single body mass when decelerating to eliminate rail car pile-up and reduce the threat of derailment.

A system and method for reducing the threat of derailment of a train during deceleration is provided. An individualized braking force for each rail car of a train, such individualized braking force being determined by the braking deceleration of the train's locomotive, may be calculated by the rail car's controller and is directly proportional to the mass of the rail car. The controller may utilize the various forces acting upon the individual rail car as measured by a plurality of sensing and measuring devices to dynamically adjust the braking force applied to the individual rail car's brakes. Such a system and method allows for the train to act as a single body mass when decelerating to eliminate rail car pile-up and reduce the threat of derailment.

A water ride including vehicles that ride on a track and using water for braking. A run-out section of the track is provided after a drop or down chute section, and the track in the run-out section runs through a pool of water at a depth causing at least a portion of a vehicle riding on the rails to contact a depth of the water to achieve vehicle braking. Significantly, the new water ride is adapted to adjust or set a variable height of the rails in the run-out chute or pool to adjust the depth of water providing water drag on a vehicle traveling through the run-out section based on the vehicle weight. A braking force is applied by the water that is proportional to vehicle weight, and the water ride may be thought of as slowing vehicles with a range of weights at about the same deceleration rate.

A water ride including vehicles that ride on a track and using water for braking. A run-out section of the track is provided after a drop or down chute section, and the track in the run-out section runs through a pool of water at a depth causing at least a portion of a vehicle riding on the rails to contact a depth of the water to achieve vehicle braking. Significantly, the new water ride is adapted to adjust or set a variable height of the rails in the run-out chute or pool to adjust the depth of water providing water drag on a vehicle traveling through the run-out section based on the vehicle weight. A braking force is applied by the water that is proportional to vehicle weight, and the water ride may be thought of as slowing vehicles with a range of weights at about the same deceleration rate.

A system and method for reducing the threat of derailment of a train during deceleration is provided. An individualized braking force for each rail car of a train, such individualized braking force being determined by the braking deceleration of the train's locomotive, may be calculated by the rail car's controller and is directly proportional to the mass of the rail car. The controller may utilize the various forces acting upon the individual rail car as measured by a plurality of sensing and measuring devices to dynamically adjust the braking force applied to the individual rail car's brakes. Such a system and method allows for the train to act as a single body mass When decelerating to eliminate rail car pile-up and reduce the threat of derailment.

A system and method for reducing the threat of derailment of a train during deceleration is provided. An individualized braking force for each rail car of a train, such individualized braking force being determined by the braking deceleration of the train's locomotive, may be calculated by the rail car's controller and is directly proportional to the mass of the rail car. The controller may utilize the various forces acting upon the individual rail car as measured by a plurality of sensing and measuring devices to dynamically adjust the braking force applied to the individual rail car's brakes. Such a system and method allows for the train to act as a single body mass When decelerating to eliminate rail car pile-up and reduce the threat of derailment.