A maintenance assembly for a wheel assembly of an amusement ride vehicle includes a foundational body, a wheel engagement section extending a first distance from the foundational body, and a datum section including a protrusion extending a second distance from the foundational body. The wheel engagement section is configured to contact a wheel surface of the wheel assembly, and the datum section is configured to contact a pad of the wheel assembly. Additionally, the wheel engagement section is rigidly positioned with respect to the datum section, and the second distance is greater than the first distance, such that the maintenance assembly provides a fixed distance between a surface of the datum section configured to contact the pad and a surface of the wheel engagement section configured to contact the wheel surface.

A maintenance assembly for a wheel assembly of an amusement ride vehicle includes a foundational body, a wheel engagement section extending a first distance from the foundational body, and a datum section including a protrusion extending a second distance from the foundational body. The wheel engagement section is configured to contact a wheel surface of the wheel assembly, and the datum section is configured to contact a pad of the wheel assembly. Additionally, the wheel engagement section is rigidly positioned with respect to the datum section, and the second distance is greater than the first distance, such that the maintenance assembly provides a fixed distance between a surface of the datum section configured to contact the pad and a surface of the wheel engagement section configured to contact the wheel surface.

A vehicle connection system in accordance with present embodiments includes a first connection mechanism having a shaft with a first portion coupled to a second portion by a hinged joint. A locking element extends from the second portion. Guides extend on opposing sides of the second portion such that a channel is formed between the guides and the guides block movement of the second portion about the hinged joint outside of the channel. The guides are positioned between the locking element and the hinged joint along the shaft. A second connection mechanism is configured to couple with the first connection mechanism and includes a locking box configured to receive the locking element via an aperture in the locking box and configured such that rotation of the locking element while in the locking box via rotation of the shaft interlocks the locking element with the lock box.

A vehicle connection system in accordance with present embodiments includes a first connection mechanism having a shaft with a first portion coupled to a second portion by a hinged joint. A locking element extends from the second portion. Guides extend on opposing sides of the second portion such that a channel is formed between the guides and the guides block movement of the second portion about the hinged joint outside of the channel. The guides are positioned between the locking element and the hinged joint along the shaft. A second connection mechanism is configured to couple with the first connection mechanism and includes a locking box configured to receive the locking element via an aperture in the locking box and configured such that rotation of the locking element while in the locking box via rotation of the shaft interlocks the locking element with the lock box.

A water ride including vehicles that ride on a track and using water for braking. A run-out section of the track is provided after a drop or down chute section, and the track in the run-out section runs through a pool of water at a depth causing at least a portion of a vehicle riding on the rails to contact a depth of the water to achieve vehicle braking. Significantly, the new water ride is adapted to adjust or set a variable height of the rails in the run-out chute or pool to adjust the depth of water providing water drag on a vehicle traveling through the run-out section based on the vehicle weight. A braking force is applied by the water that is proportional to vehicle weight, and the water ride may be thought of as slowing vehicles with a range of weights at about the same deceleration rate.

A combination chair and ottoman is adapted to convert to a slide, with the chair having a seat supported directly on a floor; and an ottoman supported directly on the floor in front of the seat, the ottoman including a lower wedge shaped section and an upper wedge shaped section hingedly connected together at common edges thereof, with the upper wedge shaped section adapted to assume a first position on top of the lower wedge shaped section to form the ottoman, and a second position pivoted upwardly on top of the seat while the lower wedge shaped section remains positioned in front of the seat to form a slide; and a first securing arrangement for securing the lower wedge shaped section to the seat when the lower wedge shaped section is positioned in front of the seat.

An amusement park ride vehicle includes a chassis, a cabin, a slider, and a rotator. The chassis is configured to direct the ride vehicle along a ride path in a direction of travel. The cabin is configured to hold one or more passengers. The slider is configured to translate between a neutral position and a cantilevered position relative to the chassis in a direction substantially transverse to the direction of travel and to carry the rotator and the cabin along the direction substantially transverse to the direction of travel. The rotator is coupled between the slider and the cabin, and is configured to rotate the cabin relative to the slider.

An amusement park ride vehicle includes a chassis, a cabin, a slider, and a rotator. The chassis is configured to direct the ride vehicle along a ride path in a direction of travel. The cabin is configured to hold one or more passengers. The slider is configured to translate between a neutral position and a cantilevered position relative to the chassis in a direction substantially transverse to the direction of travel and to carry the rotator and the cabin along the direction substantially transverse to the direction of travel. The rotator is coupled between the slider and the cabin, and is configured to rotate the cabin relative to the slider.

The present invention relates to an amusement ride (1) comprising at least one vehicle (2) which can move along a specified track (10), wherein the at least one vehicle (2) comprises at least one sensor (30), wherein the at least one sensor (30) is electrically independent of the vehicle (2), wherein the at least one sensor (30) comprises an RFID transponder (35), and wherein at least one RFID receiver (20) is arranged along the specified track (10), which is set up to communicate with the RFID transponder (35) and to read out the at least one measured value from the at least one sensor (30).

In a rollercoaster trigger system to output a data signal to a control unit for triggering and controlling an event at a predetermined track position, a beacon plate with a certain aperture pattern and a sensor set is provided to send a trigger signal and a data signal to the control unit. The sensor set includes a first and a second trigger sensor which provide together the trigger signal to readout the data of the beacon plate when together simultaneously detecting a first and second trigger aperture of the aperture pattern. A read sensor is provided for reading data from the aperture pattern by detecting a presence or absence of a read aperture. The data signal is obtained by the control unit when the trigger signal is generated.