A roller coaster with a vehicle rolling under gravity along a track defining a ride path. The vehicle includes a chassis coupled to the track to roll on one or more surfaces of the track, and the vehicle includes a passenger compartment mounted on the chassis. The coaster also includes a compartment positioning mechanism that operates to move, such as with yaw, the passenger compartment between a first position in a passenger load/unload section of the ride path and one or more differing positions in the gravity-based ride section of the ride path. The coaster includes a power supply assembly with a charging element mounted on the track. The power supply assembly includes an onboard energy storage mounted on the vehicle that is charged by the charging element. The onboard energy storage powers the compartment positioning mechanism to move the passenger compartment between the first and second positions.

A roller coaster vehicle is disclosed with seats that are mounted to a circular frame, and where the seats and the frame swing about a central horizontal axis passing between the seats, while the vehicle moves along a standard roller coaster track. The swinging or rotating of the seats with respect to the reference frame of the vehicle leads to a more intense riding experience. In a first preferred embodiment, the seats rotate passively in response to various gravitational and centripetal forces caused by the movement of the car along the track, but the seats could also be actively rotated by motors or other mechanical elements.

A roller coaster vehicle is disclosed with seats that are mounted to a circular frame, and where the seats and the frame swing about a central horizontal axis passing between the seats, while the vehicle moves along a standard roller coaster track. The swinging or rotating of the seats with respect to the reference frame of the vehicle leads to a more intense riding experience. In a first preferred embodiment, the seats rotate passively in response to various gravitational and centripetal forces caused by the movement of the car along the track, but the seats could also be actively rotated by motors or other mechanical elements.

The invention relates to a roller coaster vehicle guided along a rail structure extending in a two- or three-dimensional plane and having at least one passenger seat (3), which is fastened to a chassis (2) guided on the rail structure, wherein the passenger seat (3) is fastened to the chassis (2) by way of an axis of rotation (16, 17) extending in a longitudinal direction of the vehicle, and the rotation of the passenger seat (3) can be influenced manually during the ride of the roller coaster vehicle. According to the invention, a rotation about the axis of rotation (16, 17) can be influenced by the force of an airflow along adjustable air guiding wings (18, 19) on the vehicle.

Cabin assembly (10) for an elevator system, the cabin assembly (10) comprises a cabin (12), a chassis (14) configured to rotationally support the cabin (12) about a cabin axis (16) extending through the cabin (12), a circular thrust profile (18) arranged on the cabin (12) substantially concentric to the cabin axis (16), and a drive member (68) configured to engage the thrust profile (18) to rotate the cabin (12) about the cabin axis (16).

A track-based swing ride system providing passengers a unique swinging ride experience. The ride system includes a ride track that supports a moving bogie coupled to the ride track that includes a drive assembly driving the bogie along a ride path defined by the ride track. The ride apparatus includes a pendulum arm pivotally coupled at a first end to the bogie, whereby the pendulum arm is suspended below the ride track and moves along the ride path with the bogie. The ride apparatus includes a passenger vehicle coupled to a second end of the pendulum arm opposite the first end of the pendulum arm. To provide the swinging sensation, the ride apparatus includes a roll driver rotating, concurrently with the drive assembly of the bogie, the pendulum arm about a roll axis extending through the first end of the pendulum arm.

A track-based swing ride system providing passengers a unique swinging ride experience. The ride system includes a ride track that supports a moving bogie coupled to the ride track that includes a drive assembly driving the bogie along a ride path defined by the ride track. The ride apparatus includes a pendulum arm pivotally coupled at a first end to the bogie, whereby the pendulum arm is suspended below the ride track and moves along the ride path with the bogie. The ride apparatus includes a passenger vehicle coupled to a second end of the pendulum arm opposite the first end of the pendulum arm. To provide the swinging sensation, the ride apparatus includes a roll driver rotating, concurrently with the drive assembly of the bogie, the pendulum arm about a roll axis extending through the first end of the pendulum arm.

A roller coaster with a vehicle rolling under gravity along a track defining a ride path. The vehicle includes a chassis coupled to the track to roll on one or more surfaces of the track, and the vehicle includes a passenger compartment mounted on the chassis. The coaster also includes a compartment positioning mechanism that operates to move, such as with yaw, the passenger compartment between a first position in a passenger load/unload section of the ride path and one or more differing positions in the gravity-based ride section of the ride path. The coaster includes a power supply assembly with a charging element mounted on the track. The power supply assembly includes an onboard energy storage mounted on the vehicle that is charged by the charging element. The onboard energy storage powers the compartment positioning mechanism to move the passenger compartment between the first and second positions.

A motion assembly that produces pitch and roll motions includes lower and upper plates. A pivotable coupling having upper and lower shafts extending from its center is coupled between the upper and lower plates. At least two linear actuators are coupled between the plates. Extension and retraction of the actuators pivots the upper plate about the pivotable coupling relative to the lower plate. A vehicle includes two steerable propulsion wheels coupled to a chassis. A lower plate of a pitch and roll assembly, similar to that just described, couples to the chassis via a slew bearing. Seating is coupled to the upper plate. The seating rotates with respect to the chassis via controlled rotation of the slew bearing with reference to the chassis. The seating can be rotated to point in any direction with respect to the chassis regardless of the direction the steerable propulsion wheels move the chassis.

A motion assembly that produces pitch and roll motions includes lower and upper plates. A pivotable coupling having upper and lower shafts extending from its center is coupled between the upper and lower plates. At least two linear actuators are coupled between the plates. Extension and retraction of the actuators pivots the upper plate about the pivotable coupling relative to the lower plate. A vehicle includes two steerable propulsion wheels coupled to a chassis. A lower plate of a pitch and roll assembly, similar to that just described, couples to the chassis via a slew bearing. Seating is coupled to the upper plate. The seating rotates with respect to the chassis via controlled rotation of the slew bearing with reference to the chassis. The seating can be rotated to point in any direction with respect to the chassis regardless of the direction the steerable propulsion wheels move the chassis.