Amusement parks may have various entertainment attractions. One type of entertainment attraction may be a carousel ride system. The carousel ride system may include a turntable and multiple figures (e.g., seats for riders) that rotate with the turntable. In some carousel ride systems, the multiple figures may move up and down relative to the turntable as the multiple figures rotate with the turntable.
This section is intended to introduce the reader to various aspects of art that may be related to various aspects of the present techniques, which are described and/or claimed below. This discussion is believed to be helpful in providing the reader with background information to facilitate a better understanding of the various aspects of the present disclosure. Accordingly, it should be understood that these statements are to be read in this light, and not as admissions of prior art.
Certain embodiments commensurate in scope with the originally claimed subject matter are summarized below. These embodiments are not intended to limit the scope of the disclosure, but rather these embodiments are intended only to provide a brief summary of certain disclosed embodiments. Indeed, the present disclosure may encompass a variety of forms that may be similar to or different from the embodiments set forth below.
In an embodiment, a carousel ride system includes a first rotatable platform and multiple second rotatable platforms. Each second rotatable platform of the multiple second rotatable platforms is positioned within a respective opening in the first rotatable platform. A first drive system is configured to drive rotation of the first rotatable platform and multiple second drive assemblies are configured to drive rotation of the multiple second rotatable platforms. Multiple figures extend over the multiple second rotatable platforms and multiple figure drive assemblies are configured to independently lift and rotate the multiple figures relative to the multiple second rotatable platforms. One or more processors are configured to coordinate operation of the first drive system, the multiple second drive assemblies, and the multiple figure drive assemblies to maintain the multiple figures in a forward-facing orientation relative to a direction of travel of the first rotatable platform during operation of the carousel ride system.
In an embodiment, a drive system for a carousel ride system includes multiple figure drive assemblies configured to independently lift and rotate multiple figures of the carousel ride system. Each figure drive assembly of the multiple figure drive assemblies includes a rotation assembly having a rotation motor supported on a rotation base, a bracket coupled to the rotation base and slidingly coupled to a support post, and a sleeve coupled to the bracket and configured to couple to a pole of a respective figure of the multiple figures. Each of the multiple figure drive assemblies also includes a lift assembly having a lift motor supported on a lift base and a threaded shaft coupled to the lift base and extending through a threaded opening of the bracket. Operation of the rotation motor is configured to drive rotation of the sleeve and operation of the lift motor is configured to lift the rotation assembly.
In an embodiment, a method of operating a carousel ride system includes driving rotation of a first rotatable platform about a first rotational axis using a first drive system positioned between the first rotatable platform and a ground relative to a vertical axis. The method also includes driving rotation of multiple second rotatable platforms about respective second rotational axes using multiple second drive assemblies, wherein each second drive assembly of the multiple second drive assemblies is positioned between a respective one of the multiple second rotatable platforms and the ground relative to the vertical axis. The method further includes driving rotation and lift of multiple figures that extend over the multiple second rotatable platforms using multiple figure drive assemblies positioned between the multiple second rotatable platforms and the ground relative to the vertical axis and in a coordinated manner to maintain the multiple figures in a forward-facing orientation relative to a direction of travel of the first rotatable platform during operation of the carousel ride system.
These and other features, aspects, and advantages of the present disclosure will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
One or more specific embodiments will be described below. In an effort to provide a concise description of these embodiments, not all features of an actual implementation are described in the specification. It should be noted that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another. Moreover, it should be noted that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
When introducing elements of various embodiments of the present disclosure, the articles “a,” “an,” “the,” and “said” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements. One or more specific embodiments of the present embodiments described herein will be described below. In an effort to provide a concise description of these embodiments, all features of an actual implementation may not be described in the specification. It should be noted that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another. Moreover, it should be noted that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
The present disclosure is related to a carousel ride system that may be used in an amusement park. The carousel ride system may include a first platform (e.g., first rotatable platform), multiple second platforms (e.g., second rotatable platforms), and multiple figures (e.g., seats for riders). The figures may move up and down relative to the first platform as the figures rotate with the first platform. At least some of the figures may also rotate with a respective second platform. In an embodiment, each figure may lift (e.g., move up and down) and rotate independently from one another while maintaining a consistent forward-facing orientation to improve ride entertainment and/or comfort, for example.
In an embodiment, carousel ride operations may be programmable so that different operational modes can be performed during ride operation. For instance, some figures may lift and/or rotate, while other figures may not lift and/or rotate. In an embodiment, one or more groups of figures may lift and/or rotate in a coordinated manner, such as to provide a group of riders (e.g., a family) a racing-type experience, to face toward one another at certain times or throughout ride operation, or the like. Such operational modes may further enhance the ride experience.
With the foregoing in mind,
The first platform 12 may be a rotatable platform or table supported and driven by a first platform drive system (e.g., unified first platform drive system), which may include multiple first platform drive assemblies 20 that are located under the first platform 12. The first platform drive system, which may include the first platform drive assemblies 20, may drive the first platform 12 to rotate about a first rotational axis 54 that passes through a center of the first platform 12 and that may be parallel to a vertical axis 50. For example, as shown, the first platform drive assemblies 20 may be positioned underneath the first platform 12 (e.g., between the first platform 12 and the ground; underneath a radially-outer edge portion of the first platform 12), and the first platform drive assemblies 20 may be arranged circumferentially about the first rotational axis 54.
In the illustrated embodiment of
As illustrated, the drive units in each first platform drive assembly 20 may be connected by a connection beam 24. Each first platform drive assembly 20 may be connected to the first platform 12 by one or more support beams 26. The use of multiple first platform drive assemblies 20 along with the multiple connection beams 24 and multiple support beams 26 may help to distribute weight (e.g., of the first platform 12, the second platforms 14, the
The multiple second platforms 14 may be a set of rotatable platforms or tables supported and driven by respective second platform drive assemblies 30. As shown, a single second platform drive assembly 30 may be located under a respective second platform 14 and may be used to support and drive the respective second platform 14. Each second platform drive assembly 30 may drive the respective second platform 14 to rotate about a respective second rotational axis (e.g., second rotational axis 56A or 56B of a corresponding second platform 14) and that may be parallel to the vertical axis 50 and/or the first rotational axis 54.
As illustrated, each second platform drive assembly 30 may be positioned on a radially-extending beam 32 (e.g., spoke). In an embodiment, each radially-extending beam 32 may include one or more rods that extend radially between a respective connection beam 24 and a center post located under the first platform 12. Each radially-extending beam 32 may be fixed to (e.g., non-rotatable with respect to) the respective connection beam 24 and the center post (e.g., the center post may rotate relative to the ground), or each radially-extending beam 32 may be fixed to the respective connection beam 24 and may be rotatably coupled to (e.g., rotatable with respect to) the center post (e.g., the center post may be stationary relative to the ground). Each second platform drive assembly 30 may be connected to a respective second platform 14 by one or more support beams 34. Additionally, each second platform drive assembly 30 may be connected to a respective first platform drive assembly 20 by one or more additional connection beams 36. As shown, the second platform drive assemblies 30 may be positioned underneath the respective second platform 14 (e.g., between the respective second platform 14 and the ground; underneath a center portion of the respective second platform 14), and the second platform drive assemblies 30 may be radially-inwardly of the first platform drive assemblies 20 (e.g., between the first platform drive assemblies 20 and the center post).
Each second platform 14 may be positioned within a respective platform opening in the first platform 12. In an embodiment, each second platform 14 is not supported by the first platform 12, and is instead fully supported by its second platform drive assembly 30 and associated structures (e.g., the radially-extending beam 32) located underneath the first platform 12 and/or the second platform 14. In an embodiment, a radial gap is provided between a radially-outer surface of the second platform 14 and a radially-inner surface that defines the respective platform opening. In such cases, roller bearings may be provided within the radial gap to facilitate rotation of the second platform 14 relative to the first platform 12. It should also be appreciated that the second platforms 14 may be at least partially supported on the first platform 12, or the first platform 12 may be at least partially supported on the second platforms 14.
Each of the multiple
The first platform 12 and the second platforms 14 may be carried to travel together about the first rotational axis 54. Thus, operation of the first platform drive assemblies 20 to drive rotation of the first platform 12 about the first rotational axis 54 may result in rotation of the multiple
As mentioned previously, each of the multiple
Each figure drive assembly 40 may drive a corresponding
During ride operations, at least the first platform 12, a respective center of each of the second platforms 14, the multiple
A variety of support and drive assemblies, systems, or components may be generally hidden from the view of the riders. For example, the first platform drive assemblies 20, the rail 22, the connection beams 24, the support beams 26, the second platform drive assemblies 30, the radially-extending beams 32, the support beams 34, the additional connection beams 36, the figure drive assemblies 40, and at least a portion of each pole 18 may be positioned vertically below the first platform 12 and/or the multiple second platforms 14, enclosed by a cover (e.g., wall), and/or positioned within a receptacle (e.g., opening or hole) formed in the ground. Thus, as the riders approach the carousel ride system 10, travel across the first platform 12, and the multiple second platforms 14 during loading and unloading operations, and ride on the multiple
Additionally, it should be appreciated that various drive assemblies described in preceding sections may be powered, controlled, and coordinated by a power system and a control system (e.g., electronic control system). For example, with reference to
In an embodiment, the
As illustrated, the controller 44 may include one or more processors 45, a memory device 46, and an input device 47. The processor(s) 45 may provide control signals to certain controllable devices and components (e.g., motors, actuators, brakes, or the like) associated with the various drive assemblies (e.g., the first platform drive assemblies 20, the second platform drive assemblies 30, and the figure drive assemblies 40) and other relevant assemblies/systems. The processor(s) 45 may be configured to receive inputs via an input device 47 (e.g., from a ride operator; from a rider; from another device) and to provide the control signals to the controllable devices and components in response to the inputs. For example, the processor(s) 45 may receive an input that indicates that the riders have climbed onto the multiple
In operation, the carousel ride system 10 may continuously move between loading operations, ride operations, and unloading operations. Certain operations (e.g., ride operations) may be automated and/or controlled on one or more timers (e.g., timed schedules). For example, once rotation of the first platform 12 commences, rotations of the second platforms 14 may commence simultaneously or with a delay time. The rotation of the first platform 12 may continue for a time period (e.g., predetermined or operator-controlled time period, such as 1, 2, 3, 4, 5, or more minutes). The rotations of the second platforms 14 may continue for the same or a different time period. When the time period of the first platform 12 ends, the processor(s) 45 may provide the control signals to the controllable devices and components (e.g., motors, actuators, brakes, or the like) of the first platform 12, the second platforms 14, and the
The memory device 46 may include one or more tangible, non-transitory, computer-readable media that store instructions executable by the processor(s) 45. For example, the memory device 46 may include random access memory (RAM), read only memory (ROM), rewritable non-volatile memory such as flash memory, hard drives, optical discs, and/or the like. Additionally, the processor(s) 45 may include one or more general purpose microprocessors, one or more application specific processors (ASICs), one or more field programmable gate arrays (FPGAs), or any combination thereof.
Additionally or alternatively, individual (or distributed) controllers may be implemented. For example, the first platform drive assemblies 20, the second platform drive assemblies 30, the figure drive assemblies 40, and/or the power system 43 may have dedicated controllers (to be described in detail later) respectively. The dedicated controllers may be communicatively connected to the controller 44. The controller 44 may control and coordinate, via the respective dedicated controllers, the operations of the first platform drive assemblies 20, the second platform drive assemblies 30, the figure drive assemblies 40, and/or the power system 43.
As illustrated, the drive unit 60 may be connected to another drive unit in the same first platform drive assembly 20 by the connection beam 24. The drive unit 60 may include a frame assembly 62, one or more drive wheels 68, and a drive motor 69. The frame assembly 60 may provide support for the connection beam 24. Additionally, the frame assembly 62 may provide mounting points for the drive wheel(s) 68 and the drive motor 69. The drive motor 69 may be any type of electrical motor that generates rotational force used to drive the drive wheel(s) 68 to rotate. Although not shown here, the drive unit 60 may include other components, such as one or more brake units, one or more biasing members, one or more gearboxes, and the like.
The frame assembly 62 may include a frame 63, one or more support beams 64, and a jack 65. The frame 63 may provide direct support for the connection beam 24. The support beams 64 may be coupled to (e.g., vertically suspended from) the frame 63. The support beams 64 may be connected horizontally via a bracket 66. The support beams 64 may or may not contact the surface of the rail 22 during ride operations. The jack 65 may be coupled to (e.g., vertically suspended from) a bottom of the bracket 66).
In an embodiment, the support beams 64, or a portion (e.g., bottom portion) of the support beams 64, may be made of certain metal or plastic material that has specific abrasion and resistance properties. For example, ultra-high molecular weight (UHMW) polyethylene, which has high abrasion and impact resistance properties, may be used in the support beams 64. In the cases where the support beams 64 may contact the surface of the rail 22 during ride operations to support the frame 63 and other components, the support beams 64 (e.g., made of the UHMW polyethylene or other suitable material) may resist wear, friction, and corrosion, thus reducing maintenance cost (e.g., with less power consumption) and extending equipment/component life.
In an embodiment, a gap 67 (e.g., along the vertical axis 50) may be provided between the support beams 64 and a top surface of the rail 22 (e.g., during default or expected operation; while a wear level or thickness of the drive wheels 68 is above a threshold). In such cases, a sensor (e.g. contact sensor or position sensor) and/or a scraper (or scraper blade) may be installed on the support beams 64. The sensor may be used to detect whether the support beams 64 contact or are within a threshold distance of the top surface of the rail 22. The sensor may generate a signal in response to the detected event, and the signal may indicate a corresponding (e.g., nearest) drive wheel 68 has experienced too much wear (e.g., the wear level or the thickness is below the threshold) during ride operations. The scraper or scraper blade may be used to clean the rail 22 to remove possible debris or fallen objects during ride operations to avoid potential halt/damage to the first platform drive wheel 68.
As illustrated, the jack 65 may have a pre-attached pad, which may prevent possible delamination (e.g., to the rail 22) during ride operations when one or more drive wheels 68 wear out or a similar situation occurs. In some cases, the jack 65 may be a portable jack for maintenance (e.g. used to support the frame 63 and other components while replacing the drive wheel 68).
Additionally, it should be appreciated that the operations of the first platform drive assembly 20 may be coordinated and controlled by a controller 144 (e.g., electronic controller). The controller 144 may control and coordinate the operations of the drive units 60. For example, the controller 144 may control the drive motors 69 and/or the brakes to start or stop the rotation of the first platform 12. In an embodiment, the controller 144 may adjust speed settings of the drive motors 69 to control a rotation speed of the first platform 12.
The controller 144 may include one or more processors 145, a memory device 146, and an input device 147. The processor(s) 145 may provide control signals to certain controllable devices and components (e.g., motors, actuators, brakes, or the like) associated with the first platform drive assemblies 20 and other relevant assemblies/systems. The processor(s) 145 may be configured to receive inputs via an input device 147 (e.g., from a ride operator; from riders; from a computing device) and to provide the control signals to the controllable devices and components in response to the inputs.
Further, the processor(s) 145 may receive a signal generated by a sensor in response to the detected event (e.g. one of the support beams 64 contacting or being within the threshold distance of the rail 22) during a ride operation. The processor(s) 145 may respond to the received signals. For example, if the ride operation is near an end, the processor(s) 145 may determine and/or send an instruction to the control system 44 that the ongoing ride operation may proceed until reaching the end. In an embodiment, where multiple sensors are installed (e.g., on multiple support beams 64), the processor(s) 145 may determine and/or instruct continuing or terminating the ride operation based on a number of support beams 64 in contact with or within the threshold distance of the rail 22. For example, if the processor(s) 145 receives a signal from one sensor indicating a contacting event has been detected during a ride operation, the processor(s) 145 may determine and/or send an instruction to the controller 44 that the ride operation may proceed. However, when the processor(s) 145 receives signals from both sensors installed on the paired support beams 64 of one drive unit 60 or from multiple sensors installed on multiple support beams 64 of multiple drive units 60, the processor(s) 145 may determine and/or send an instruction to the controller 44 that the ride operation should be terminated. In response, the controller 44 may instruct a suitable action, such as to maintain the ride operation, stop the ride operation, and/or provide a notification for repair (e.g., to a ride operator).
The memory device 146 may include one or more tangible, non-transitory, computer-readable media that store instructions executable by the processor(s) 145. For example, the memory device 146 may include random access memory (RAM), read only memory (ROM), rewritable non-volatile memory such as flash memory, hard drives, optical discs, and/or the like. Additionally, the processor(s) 145 may include one or more general purpose microprocessors, one or more application specific processors (ASICs), one or more field programmable gate arrays (FPGAs), or any combination thereof.
During ride operations, each second platform 14, a group of the multiple
As illustrated, the second platform drive assembly 30 shown here may include a plate assembly 70 and one or more drive wheel assemblies 76. The plate assembly 70 may provide a rotation base for the second platform 14 mounted on top of the plate assembly 70. The drive wheel assembly 76 may provide the drive force for the plate assembly 70.
The plate assembly 70 may include a fixed plate 71 (e.g., fixed to the radially-extending beam 32), a rotatable plate 72 (e.g., rotatable relative to the fixed plate 71), and a bearing plate 73 between the fixed plate 71 and the rotatable plate 72. The fixed plate 71 may be positioned on top of the radially-extending beam 32. Additionally, the fixed plate 71 may be connected to a corresponding first platform drive assembly 20 by one or more additional connection beams 36. The bearing plate 73 is placed under the rotatable plate 72 to distribute the load (e.g., combined weight from the second platform 14 and the group of the multiple
Both the fixed plate 71 and the rotatable plate 72 may have radially-outer (e.g., donut-shaped, ring-shaped, annular) surfaces. In an embodiment, both the fixed plate 71 and the rotatable plate 72 may have hollow structural sections to provide a low-weight structure, thus increasing driving efficiency of the drive wheel assemblies 76 during ride operations.
In an embodiment, the fixed plate 71, the rotatable plate 72, and the bearing plate 73 may be concentric (e.g., centered about the second rotational axis 56A). The inner diameters of the fixed plate 71, the rotatable plate 72, and the bearing plate 73 may be same or similar to each other, while the outer diameters may be different. For example, the fixed plate 71 may have a larger outer diameter than the rotatable plate 72 and the bearing plate 73. The bearing plate 73 may have a smaller outer diameter than the fixed plate 71 and the rotatable plate 72.
The drive wheel assemblies 76 may include a drive wheel 77, a wheel holder 78, and a drive motor 79. Driven by the drive motor 79, the drive wheel 77 may be movable along the radially-outer surface of the fixed plate 71. The wheel holder 78, which may be placed between the drive wheel 77 and the drive motor 79, may be used to hold the drive wheel 77 onto the radially-outer surface of the fixed plate 71. The wheel holder 78 may have certain contact parts (e.g., extended from the main body of the wheel holder 78 toward the rotatable plate 72) that may contact the radially-outer surface of the rotatable plate 72. Therefore, rotation of the drive wheel 77 (e.g., about a rotational axis 58) may drive the rotatable plate 72 to rotate about the second rotational axis 56A, accordingly driving the second platform 14 to rotate about the second rotational axis 56A during ride operations.
It should be appreciated that the wheel holder 78 may contact the fixed plate 71 and the drive wheel 77 may move along the radially-outer surface of the rotatable plate 72. The drive motor 79 may be any type of electrical motor that generates the rotational force used to drive the drive wheel(s) 77 to rotate. Although not shown here, the drive wheel assemblies 76 may include other components, such as one or more brake units, one or more biasing members, one or more gearboxes, and the like.
Additionally, it should be appreciated that the operations of the second platform drive assemblies 30 may be coordinated and controlled by a controller 154 (e.g., electronic controller). The controller 154 may control and coordinate the operations of the plate assemblies 70 and drive wheel assemblies 76. For example, the controller 154 may control one or more drive motors 79 and/or associated brakes to start or stop one or more rotations of the second platforms 14. In an embodiment, the controller 154 may adjust speed settings of the drive motors 79 to control a rotational speed of the second platform 14.
The controller 154 may include one or more processors 155, a memory device 156, and an input device 157. The processor(s) 155 may provide control signals to certain controllable devices and components (e.g., motors, actuators, brakes,) associated with the second platform drive assemblies 30 and other relevant assemblies/systems. The processor(s) 155 may be configured to receive inputs via an input device 157 (e.g., from a ride operator; from a rider) and to provide the control signals to the controllable devices and components in response to the inputs. For example, during certain ride operations, one or more second platforms 14 may be reserved for special events (e.g. family rides) that allow adults to ride with children. Accordingly, certain
The memory device 156 may include one or more tangible, non-transitory, computer-readable media that store instructions executable by the processor(s) 155. The adjustable rotational speed of the reserved second platforms 14 may be stored in the memory device 156 so that the preferred operations related to the family ride events may be performed automatically via the processor(s) 155 with or without the operator's supervisions. The memory device 156 may include random access memory (RAM), read only memory (ROM), rewritable non-volatile memory such as flash memory, hard drives, optical discs, and/or the like. Additionally, the processor(s) 155 may include one or more general purpose microprocessors, one or more application specific processors (ASICs), one or more field programmable gate arrays (FPGAs), or any combination thereof.
Turning to
A support assembly 80 may be used to provide support for the pole 18 and to provide mounting points for a lift assembly 100 and a rotation assembly 120. The lift assembly 100 may drive the pole 18 to move up and down along the figure axis 55 during ride operations. The rotation assembly 120 may drive the pole 18 to rotate about the figure axis 55 during ride operations. With the figure drive assembly 40 and the resulting increased operational flexibility of the carousel ride system 10, the ride guests may have a more enjoyable riding experience.
The support assembly 80 may include a post 82 mounted on a base plate 84. As shown, one or more ribs 86 may be installed (e.g., welded) between the lower portion of the post 82 and the base plate 84 to reinforce the joint between the post 82 and the base plate 84, therefore increasing the stability of the pole 18 and the corresponding
The lift assembly 100 may include a lift motor 101 installed on a lift motor base 102. The lift motor base 102 may be mounted on the base plate 84. A threaded shaft 103 (e.g., ball screw) may be installed with one end rotatably coupled to the lift motor base 102, and another end rotatably coupled to a shaft bracket 104 that is mounted on the post 82. The threaded shaft 103 may be utilized in conjunction with bearings (e.g., ball bearings) to facilitate rotation of the threaded shaft 103. The lift motor 101 may be any type of electrical motor that generates the rotational force used to drive the threaded shaft 103 to rotate. The lift motor base 102 may include gears (e.g., spur gears and/or other types of gears) that may transfer motion (e.g., rotations) from an output shaft of the lift motor 101 to the threaded shaft 103. The threaded shaft 103 extend through a threaded opening in a mounting bracket 106, and the rotation of the threaded shaft 103 may drive linear movement of the mounting bracket 106 (and the components, such as the pole 18, supported on the mounting bracket 106) along the figure axis 55.
The threaded shaft 103 may thus be considered a linear actuator that translates rotational motion to linear motion with little friction. It should be appreciated that an additional and/or alternative driving mechanism may be utilized. For example, other types of linear actuators may be used to translate rotational motions to linear motions.
As shown, a pair of mounting brackets 105 and 106 are mounted on the support assembly 80. At least one of the mounting brackets (e.g., mounting bracket 106) may have the threaded opening to accept the threaded shaft 103. The mounting bracket 105 may be coupled to a pair of guides 107. Similarly, the mounting bracket 106 may be coupled to another pair of guides 108. Both the pair of guides 107 and the pair of guides 108 may move freely along a pair of rails 109 that are mounted on the post 82.
In addition to translational motions provided by the lift assembly 100, rotational motions may be provided by the rotation assembly 120. The rotation assembly 120 may include a rotation motor 121 installed on a rotation motor base 122. The rotation motor base 122 may be coupled to the mounting bracket 106 and to a sleeve 123 (e.g., rod). The rotation motor 121, the rotation motor base 122, the mounting bracket 106, the sleeve 123, and/or the pole 18 may translate along the figure axis 55 via operation of the lift assembly 100. Additionally, the sleeve 123 and the pole 18 coupled thereto may be driven to rotate about the figure axis 55 via operation of the rotation assembly 120. The rotation motor 121 may be any type of electrical motor that generates the rotational force used to drive the sleeve 123 to rotate. The rotation motor base 122 may include gears (e.g., spur gears and/or other types of gears) that may transfer rotation from an output shaft of the rotation motor 121 to the sleeve 123.
As the sleeve 123 is coupled to the pole 18, motions of the sleeve 123, including translational motions along the figure axis 55 and rotational motion about the figure axis 55, may be transferred to motions of the pole 18, which in turn may be transferred to motions of the
Additionally, it should be appreciated that the operations of the figure drive assembly 40 may be coordinated and controlled by a controller 164 (e.g., electronic controller). The controller 164 may control and coordinate the operations of the lift assembly 100 and rotation assembly 120. For example, the controller 164 may control the lift motor 101 to cause the corresponding
The controller 164 may include one or more processors 165 and a memory device 166. The processor(s) 165 may provide control signals to certain controllable devices and components (e.g., motors, actuators, brakes, or the like) associated with the individual lift and rotate system 40 and other relevant assemblies/systems. The processor(s) 165 may be configured to receive inputs via an input device 167 (e.g., from a ride operator, from riders, from a computing device) and to provide the control signals to the controllable devices and components in response to the inputs. For example, certain
The memory device 166 may include one or more tangible, non-transitory, computer-readable media that store instructions executable by the processor(s) 165. In the example of figure maintenance described above, the identification of
The central figure drive assembly 200 may include a center mast 206 that extends vertically upwardly from a floor 208 (e.g., ground). A
A motor 230 and/or a gear assembly 232 may be provided to drive the movement of the figure support assembly 212 and the
In operation, the motor 230 may be controlled to adjust the central figure drive assembly 200 to the loading configuration 202 in which the
It should be appreciated that the central figure drive assembly 200 may be utilized to drive figures in any of a variety of carousel ride systems. For example, the central figure drive assembly 200 may be utilized to drive the
While only certain features of present embodiments have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes that fall within the true spirit of the disclosure. Further, it should be understood that certain elements of the disclosed embodiments may be combined or exchanged with one another.
The techniques presented and claimed herein are referenced and applied to material objects and concrete examples of a practical nature that demonstrably improve the present technical field and, as such, are not abstract, intangible or purely theoretical. Further, if any claims appended to the end of this specification contain one or more elements designated as “means for [perform]ing [a function] . . . ” or “step for [perform]ing [a function] . . . ”, it is intended that such elements are to be interpreted under 35 U.S.C. 112(f). However, for any claims containing elements designated in any other manner, it is intended that such elements are not to be interpreted under 35 U.S.C. 112(f).
This application claims priority to and the benefit of U.S. Provisional Application No. 63/050,908, entitled “CAROUSEL RIDE SYSTEM,” filed Jul. 13, 2020, which is hereby incorporated by reference in its entirety for all purposes.
Number | Date | Country | |
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63050908 | Jul 2020 | US |