A track section for a ride having a vehicle, divided into a first block segment and a second block segment. The first block segment has a first high point and ends at a second high point. The second block segment begins at the second high point. A first linear drive is situated before the first high point, and a second linear drive is situated between the first high point and the second high point. The positions of the high points relative to one another and the design of the linear drives are coordinated so the vehicle can be brought to a standstill in the first block segment if entry into the second block segment is not enabled. A method for traveling over the track section is provided, wherein a change in direction of travel of the vehicle is produced if the second block segment is not enabled for entry.

A track section for a ride having a vehicle, divided into a first block segment and a second block segment. The first block segment has a first high point and ends at a second high point. The second block segment begins at the second high point. A first linear drive is situated before the first high point, and a second linear drive is situated between the first high point and the second high point. The positions of the high points relative to one another and the design of the linear drives are coordinated so the vehicle can be brought to a standstill in the first block segment if entry into the second block segment is not enabled. A method for traveling over the track section is provided, wherein a change in direction of travel of the vehicle is produced if the second block segment is not enabled for entry.

The invention is a car for a fairground ride with at least one axle arranged on a rotatable carrier structure and a coupling element for coupling a further car, wherein the coupling element is movably mounted and connected to the carrier structure via a mechanical operative connection so that a movement of the coupling element leads to a rotation of the carrier structure and of the wheel axle arranged thereon and a rotation of the rotatable carrier structure leads to a movement of the coupling element, and a method for controlling the rotation of a mounted carrier structure of a wheel axle of a car of a fairground ride with a coupling element for a further car, wherein a position change of the relative position of the car in relation to another is translated into a position change of the coupling element.

The invention is a car for a fairground ride with at least one axle arranged on a rotatable carrier structure and a coupling element for coupling a further car, wherein the coupling element is movably mounted and connected to the carrier structure via a mechanical operative connection so that a movement of the coupling element leads to a rotation of the carrier structure and of the wheel axle arranged thereon and a rotation of the rotatable carrier structure leads to a movement of the coupling element, and a method for controlling the rotation of a mounted carrier structure of a wheel axle of a car of a fairground ride with a coupling element for a further car, wherein a position change of the relative position of the car in relation to another is translated into a position change of the coupling element.

A tower ride is disclosed with suspended cars mounted on rails that that forms track that is a complete double helix path for the car without having to turn the car or switch tracks. The car is suspended from a four truss track, riding on the two bottom rails for stability. Another embodiment is a roller coaster track mounted on a tower.

A tower ride is disclosed with suspended cars mounted on rails that that forms track that is a complete double helix path for the car without having to turn the car or switch tracks. The car is suspended from a four truss track, riding on the two bottom rails for stability. Another embodiment is a roller coaster track mounted on a tower.

A ride system includes a tunnel, a vehicle ride path, a ride vehicle, and a projection system. The tunnel includes a first end and a second end and is curved between the first and second ends. The vehicle ride path extends within the tunnel from an entrance at the first end of the tunnel to an intermediate position within the tunnel. The second end of the tunnel is not visible from the intermediate position. The ride vehicle travels along the vehicle ride path and decelerates as the ride vehicle approaches the intermediate position. The projection system projects images onto one or more walls of the tunnel, such that the images are synchronized with the deceleration of the ride vehicle and a perceived speed of the ride vehicle, as perceived by a guest in the ride vehicle, exceeds an actual speed of the ride vehicle.

A ride system includes a tunnel, a vehicle ride path, a ride vehicle, and a projection system. The tunnel includes a first end and a second end and is curved between the first and second ends. The vehicle ride path extends within the tunnel from an entrance at the first end of the tunnel to an intermediate position within the tunnel. The second end of the tunnel is not visible from the intermediate position. The ride vehicle travels along the vehicle ride path and decelerates as the ride vehicle approaches the intermediate position. The projection system projects images onto one or more walls of the tunnel, such that the images are synchronized with the deceleration of the ride vehicle and a perceived speed of the ride vehicle, as perceived by a guest in the ride vehicle, exceeds an actual speed of the ride vehicle.

Systems and methods for braking or launching a ride vehicle are disclosed. In one embodiment, a system includes a linear induction motor (LIM) installed in a curved portion of a track, a ride vehicle disposed upon the track, one or more reaction plates coupled to a side of the ride vehicle facing the track via a plurality of actuators, one or more sensors configured to monitor an air gap between the one or more reaction plates and the LIM, and a processor configured to determine which of the plurality of actuators to actuate and a desired performance of each of the plurality of actuators based on data received from the one or more sensors to maintain the air gap at a desired level throughout traversal of the curve by the ride vehicle.

Systems and methods for braking or launching a ride vehicle are disclosed. In one embodiment, a system includes a linear induction motor (LIM) installed in a curved portion of a track, a ride vehicle disposed upon the track, one or more reaction plates coupled to a side of the ride vehicle facing the track via a plurality of actuators, one or more sensors configured to monitor an air gap between the one or more reaction plates and the LIM, and a processor configured to determine which of the plurality of actuators to actuate and a desired performance of each of the plurality of actuators based on data received from the one or more sensors to maintain the air gap at a desired level throughout traversal of the curve by the ride vehicle.