Dark ride system 1 typically comprises a ride space; a set of wirelessly-controlled and tracklessly-guided passenger vehicle platforms 10 dispatchable within the ride space; a set of wirelessly-controlled and tracklessly-guided themed scenery vehicle platforms dispatchable within the ride space; a load and unload area for passengers disposed proximate the ride space; and a control system. A predetermined set of passengers is allowed to board a predetermined subset of the set of wirelessly-controlled and tracklessly-guided passenger vehicle platforms at the load and unload area and the set of wirelessly-controlled and tracklessly-guided themed scenery vehicle platforms dispatched in an initial spatial arrangement at one or more predetermined times. During a ride show, the control system choreographs and changes a predetermined subset of the set of wirelessly-controlled and tracklessly-guided themed scenery vehicle platforms. At a conclusion of the ride show, the predetermined set of passengers are allowed to exit.

Dark ride system 1 typically comprises a ride space; a set of wirelessly-controlled and tracklessly-guided passenger vehicle platforms 10 dispatchable within the ride space; a set of wirelessly-controlled and tracklessly-guided themed scenery vehicle platforms dispatchable within the ride space; a load and unload area for passengers disposed proximate the ride space; and a control system. A predetermined set of passengers is allowed to board a predetermined subset of the set of wirelessly-controlled and tracklessly-guided passenger vehicle platforms at the load and unload area and the set of wirelessly-controlled and tracklessly-guided themed scenery vehicle platforms dispatched in an initial spatial arrangement at one or more predetermined times. During a ride show, the control system choreographs and changes a predetermined subset of the set of wirelessly-controlled and tracklessly-guided themed scenery vehicle platforms. At a conclusion of the ride show, the predetermined set of passengers are allowed to exit.

The present invention relates to an amusement ride (1), having a frame (10) that can be rotated about a vertical axis (Z), with at least one first seat row arrangement (20) with a linkage (30), at least one row of seats (40), each with at least one seat (41) for a passenger, and a lifting device (50), the at least one row of seats (40) being connected to the linkage (30) via a joint (45), the linkage (30) connecting the joint (45) to the frame (10), and the lifting device (50) being able to lift the row of seats (40) in the orientation of the vertical axis (Z).

The present invention relates to an amusement ride (1), having a frame (10) that can be rotated about a vertical axis (Z), with at least one first seat row arrangement (20) with a linkage (30), at least one row of seats (40), each with at least one seat (41) for a passenger, and a lifting device (50), the at least one row of seats (40) being connected to the linkage (30) via a joint (45), the linkage (30) connecting the joint (45) to the frame (10), and the lifting device (50) being able to lift the row of seats (40) in the orientation of the vertical axis (Z).

An amusement park system in accordance with present embodiments includes multiple separated park areas, an autonomous vehicle configured to drive along ground surfaces within the multiple separated park areas, and a gondola system configured to transport the autonomous vehicle between the multiple separated park areas. The amusement park system further includes a control system configured to operate the autonomous vehicle to engage with and disengage from the gondola system to facilitate transport of the autonomous vehicle by the gondola system.

A gap blocking system includes a loading platform having a gap separating a first portion of the loading platform from a second portion of the loading platform. A ride vehicle is coupled to a transport extending through the gap. The gap blocking system also includes a panel assembly coupled to the loading platform and comprising a plurality of panels, wherein each panel of the plurality of panels is coupled to a respective biasing mechanism coupled to the first portion of the loading platform and configured to bias each panel towards a closed configuration in which each panel extends radially away from the first portion of the loading platform.

A gap blocking system includes a loading platform having a gap separating a first portion of the loading platform from a second portion of the loading platform. A ride vehicle is coupled to a transport extending through the gap. The gap blocking system also includes a panel assembly coupled to the loading platform and comprising a plurality of panels, wherein each panel of the plurality of panels is coupled to a respective biasing mechanism coupled to the first portion of the loading platform and configured to bias each panel towards a closed configuration in which each panel extends radially away from the first portion of the loading platform.

There is provided a system for providing interactivity to a guest of an experiential venue, based on sensor measurement of the guest. The system comprises a sensor configured to sense a guest variable of the guest, where the sensor may be a biometric sensor, a facial recognition sensor, a voice stress analysis sensor, a gesture recognition sensor, a motion tracking sensor, or an eye tracking sensor, and may sense heart rate or another guest variable. The system also comprises a control system, which may be implemented as a computer, in communication with the sensor. The control system is configured to determine a guest state from the guest variable, and to modify a venue variable, for example by selecting a path a theme park ride follows. The control system modifies the venue variable according to the guest state to provide increased satisfaction to the guest of the experiential venue.

There is provided a system for providing interactivity to a guest of an experiential venue, based on sensor measurement of the guest. The system comprises a sensor configured to sense a guest variable of the guest, where the sensor may be a biometric sensor, a facial recognition sensor, a voice stress analysis sensor, a gesture recognition sensor, a motion tracking sensor, or an eye tracking sensor, and may sense heart rate or another guest variable. The system also comprises a control system, which may be implemented as a computer, in communication with the sensor. The control system is configured to determine a guest state from the guest variable, and to modify a venue variable, for example by selecting a path a theme park ride follows. The control system modifies the venue variable according to the guest state to provide increased satisfaction to the guest of the experiential venue.

A quick disconnect system for an accessory electrically coupled to a component of an amusement attraction includes a multi-part electrical enclosure including a first side, a second side opposite the first side, a first opening on the first side, and a relief pass through. The multi-part electrical enclosure is configured to: have a first electrical cable coupled to the accessory pass into the multi-part electrical enclosure via the first opening and have a second electrical cable pass into the second side of the multi-part electrical enclosure to enable the first and second cables to be coupled together within the multi-part electrical enclosure. The relief pass through is configured to provide strain relief to both the first electrical cable and the second electrical cable and to prevent disconnection of the accessory from the multi-part electrical enclosure.