A capsule ride system includes a capsule, where the capsule includes a drum, which may include a curved annular wall that may define a chamber. The capsule also includes a platform that may fit within the chamber and that supports a restraint for a passenger. The system further includes a drive system capable of driving rotation of the capsule about a central axis of the capsule and driving forward and/or rearward movement of the capsule along a track.

A motion simulator ride assembly includes a motion base and a rider support assembly positioned beneath and coupled to the motion base. The rider support assembly includes a plurality of rider support units, each rider support unit of the one or more rider support units having an inversion table having a surface that may abut a rider. The inversion table may rotate about an axis to transition between a loading configuration and a ride configuration and the ride configuration positions the rider in a substantially facedown position. Each rider support unit also includes a restraint system that may secure the rider onto the inversion table. The restraint system includes a first moveable restraint and a second moveable restraint that are each coupled to the inversion table and the first and second moveable restraints may move relative to the surface to move the first and second movable restraints from an unrestrained configuration to a restrained configuration. The motion simulator ride assembly also includes a display screen that may project a simulated environment. The display screen is positioned below the motion base.

A simulator ride may include an annular structure forming at least a partial annulus on which a path is implemented. Additionally, the simulator ride may include a headset with a display designed to be worn by a passenger. A passenger support system may be coupled to the path of the annular structure and designed to move along the path and rotate about a center axis of the annular structure when in operation. Additionally, the annular structure may be configured to be articulated in one or more degrees of freedom.

A capsule ride system includes a capsule, where the capsule includes a drum, which may include a curved annular wall that may define a chamber. The capsule also includes a platform that may fit within the chamber and that supports a restraint for a passenger. The system further includes a drive system capable of driving rotation of the capsule about a central axis of the capsule and driving forward and/or rearward movement of the capsule along a track.

A motion simulator ride assembly including a motion base and a rider support assembly positioned beneath and coupled to the motion base. The rider support assembly includes a plurality of rider support units each including a saddle having a leading end, a tail end, and a superior surface that may support a rider in a facedown position and a restraint system that may secure the rider onto the rider support. The restraint system includes a rotating restraint having an attachment point on the saddle, and the rotating restraint may move relative to the superior surface to move the rotating restraint from an unrestrained configuration to a restrained configuration, and the rotating restraint may abut against a posterior surface of a torso of the rider when the rotating restraint is in the restrained configuration. The motion simulator ride assembly also includes a display screen that may project a simulated environment. The display screen is positioned below the motion base.

A simulator ride may include an annular structure forming at least a partial annulus on which a path is implemented. Additionally, the simulator ride may include a headset with a display designed to be worn by a passenger. A passenger support system may be coupled to the path of the annular structure and designed to move along the path and rotate about a center axis of the annular structure when in operation. Additionally, the annular structure may be configured to be articulated in one or more degrees of freedom.

A motion simulator ride assembly includes a motion base and a rider support assembly positioned beneath and coupled to the motion base. The rider support assembly includes a plurality of rider support units, each rider support unit of the one or more rider support units having an inversion table having a surface that may abut a rider. The inversion table may rotate about an axis to transition between a loading configuration and a ride configuration and the ride configuration positions the rider in a substantially facedown position. Each rider support unit also includes a restraint system that may secure the rider onto the inversion table. The restraint system includes a first moveable restraint and a second moveable restraint that are each coupled to the inversion table and the first and second moveable restraints may move relative to the surface to move the first and second movable restraints from an unrestrained configuration to a restrained configuration. The motion simulator ride assembly also includes a display screen that may project a simulated environment. The display screen is positioned below the motion base.

This invention is an amusement apparatus. In particular, a player can ride a rolling toy, for example, a bicycle or a scooter, inside a rotating tube, so the riding is emulated. The player holds controlling devices, which control the rotation speed. A multi-functional digital module is installed statically inside the tube. It can detect player's position, receive control signal, and project synchronized 3D animation in front of the player, so a virtual 3D animation is presented.

A gondola 40 is mounted to move freely along an endless, sinuous track 20. With the track 20 rotating about a horizontal axis, the gondola 40 is raised and, as the track 20 presents a downhill section, the gondola 40 rolls down it under the influence of gravity. The steeper the downhill section, the greater the speed until the gondola 40 reaches its lowermost position (FIG. 1B). Its momentum cause the gondola 40 to carry on travelling along a momentarily uphill section of the track 20. Travel from then on depends on a number of variables, including the rotational speed, direction and acceleration of the track 20, the weight of the gondola 40 and its passengers, the natural damping effect of friction in the mounting of the gondola 40 on the track 20, and any additional braking and/or driving effect that may be applied to the gondola 40. As compared to a conventional rollercoaster, the ride 1 may occupy a very much smaller footprint, incur a much lower capital cost and be readily adaptable to mobile use. By varying the operating parameters, many differing ride experiences may be achieved.

A recreational slide system is disclosed. The recreational slide system includes a support structure and a slide operatively supported by the support structure and rotatable relative to the support structure and about a rotational axis of the slide. The slide includes a tubular slide body that extends between an entrance opening and an opposite exit opening. In particular, the slide body defines a slide surface that is non-wet lubricated over which a rider is configured to travel as the slide is rotated. The recreational slide system includes at least one drive that is operatively coupled to the slide. The at least one drive is configured to rotate the slide about the rotational axis.