Systems and methods for energy storage and management may be useful for a variety of applications, including launch devices. A system can include a direct current (DC) bus configured to operate within a predetermined range of voltages. The system can also include an array comprising a plurality of ultra-capacitors connected to the DC bus and configured to supply the DC bus with energy. The system can further include an input configured to receive energy from a power grid, wherein the power grid is configured to supply fewer than 250 amps of power. The system can additionally include an output configured to supply more than 250 amps of power. The system can also include a controller configured to control charging and discharging of the array of ultracapacitors and configured to control the DC bus to remain within the predetermined range of voltages.

A ride vehicle control system for a ride vehicle of an attraction includes multiple sensors that are configured to monitor a guest supported by the ride vehicle. The ride vehicle control system also includes an actuator system configured to couple to the ride vehicle. The ride vehicle control system further includes one or more processors that are configured to receive signals from the multiple sensors, wherein the signals are indicative of a position of the guest, a movement of the guest, or both. The one or more processors are also configured to determine an intended movement for the ride vehicle based on the signals and to control the actuator system to adjust a resistance to movement of the ride vehicle to facilitate the intended movement.

Embodiments of the present disclosure relate to an amusement park attraction installation including a camera disposed on a side of a window, where the camera includes a lens and is configured to capture image data indicative of movement of a guest on an opposite side of the window. The amusement park attraction installation also includes a light source positioned on the side of the window and a camera housing disposed at least partially about the camera, where the camera housing has an inner volume and an opening surrounded by an edge of the camera housing, the lens is disposed within the inner volume, and the edge of the camera housing is in abutment with a surface of the window.

The roller coaster with separable cars and multiple paths is a mechanical structure. The roller coaster with separable cars and multiple paths incorporates a plurality of trolleys, a track structure, and a control structure. The control structure controls the motion of the plurality of trolleys through the track structure. Each individual trolley selected from the plurality of trolleys travels along the track structure either as a train or as in individual trolley. Each individual trolley can both separate from the train and rejoin the train as the individual trolley travels through the track structure. The track structure is a multipath structure. The track structure forms a circuit. The track structure forms the path that guides each the plurality of trolleys through the circuit formed by the track structure. Each individual trolley can take an individual path selected from the multipath structure of the track structure.

The roller coaster with separable cars and multiple paths is a mechanical structure. The roller coaster with separable cars and multiple paths incorporates a plurality of trolleys, a track structure, and a control structure. The control structure controls the motion of the plurality of trolleys through the track structure. Each individual trolley selected from the plurality of trolleys travels along the track structure either as a train or as in individual trolley. Each individual trolley can both separate from the train and rejoin the train as the individual trolley travels through the track structure. The track structure is a multipath structure. The track structure forms a circuit. The track structure forms the path that guides each the plurality of trolleys through the circuit formed by the track structure. Each individual trolley can take an individual path selected from the multipath structure of the track structure.

An amusement park attraction effects system includes a dynamic display for viewing by a user traveling through an attraction, a display monitor to provide status data indicative of a status of the dynamic display, a location identification system to determine a location of the user, a thrust-vectoring flow effect generator to generate and direct a fluid flow toward any particular target location of a range of target locations, and an automation controller communicatively coupled to the display monitor, the location identification system, and the thrust-vectoring flow effect generator. The automation controller is configured to receive the status data, receive the location of the user, set a target location based on the location of the user, instruct the thrust-vectoring flow effect generator to direct the fluid flow based on the target location, and instruct the thrust-vectoring flow effect generator to control the fluid flow based on the status data.

The invention relates to a synchronization device for synchronizing head-mounted displays (22) in an amusement ride (10), comprising at least one head-mounted display (22) with which a virtual reality generated by a VR device (30) can be displayed, and a display position detection device (28) for detecting the position and orientation of the head-mounted display (22), the synchronization device (12) being set up in such a way that the virtual reality is synchronized with the head-mounted display (22), taking into account the position and orientation of the head-mounted display (22) detected by the display position detection device (28), as soon as a selectable start criterion is met. Furthermore, the invention relates to an amusement ride having a synchronization device of this type. Furthermore, the invention relates to a method for operating an amusement ride of this type.

Present systems and methods are directed to a ride system that includes a personal electronic device (PED) holding system for a ride vehicle. The PED holding system includes a lock that is configured to move from an unlocked configuration to a locked configuration to lock a PED of a passenger of the ride vehicle to the ride vehicle during a ride cycle. The PED holding system also includes a charging system that is configured to charge an energy storage component of the PED during the ride cycle.

A system includes a plurality of rotatable track members that guide travel of a vehicle. Each rotatable track member of the plurality of rotatable track members is configured to individually rotate between a first orientation along a first direction of vehicle travel and a second orientation along a second direction of vehicle travel.

A system includes a plurality of rotatable track members that guide travel of a vehicle. Each rotatable track member of the plurality of rotatable track members is configured to individually rotate between a first orientation along a first direction of vehicle travel and a second orientation along a second direction of vehicle travel.