This application is a U.S. national stage of PCT/EP2019/080720 filed on 8 Nov. 2019 which claims priority to and the benefit of European Application No. 18205541.8 filed on 9 Nov. 2018 the contents of which are incorporated herein by reference in their entireties.
The present invention relates to an amusement device. In particular, the amusement device according to the invention is used, for example, in funfairs and theme parks, and in particular is an amusement device, comprising a plurality of seats that are mounted in a movable manner with respect to a central shaft.
Different amusement device, provided with seats that are moved around a central shaft are known in the art.
As an example, carousels are known, where a plurality of seats are mounted in a rotatable manner around a central shaft. The users of the amusement device are thus moved around a circular path. The experience of the user is thus repetitive over time. Some modifications have been devised to enhance the experience of carousels, e.g. the seats may be also movable in a vertical manner with respect to the shaft. The experience of the user is somewhat more diversified, but still repetitive, e.g. a first user is always looking toward a second user.
It has been proposed to provide the user with visors, to let them experience a virtual reality during the ride. Such a solution provides an improved experience, but it is complex and expensive.
Amusement devices where the users are mainly moved along a vertical direction are also known (the so called “towers”). In these amusement devices, the user are lifted and then suddenly and rapidly lowered, to provide a feeling of a fall. These amusement devices provide thrill and excitement to the user, but these feeling are mainly provided by the fall, i.e. by a short amount of time.
GB190717873 discloses an amusement device comprising a revolving support and a plurality of arms, rotatable around shafts arranged at right angles one with respect to the other, and mounted orthogonally with respect to the revolving support. A motor is placed at the bottom of the revolving support, to control rotation of the revolving support. The shafts that support the arms are integral in rotation with the revolving support, and are provided with bevel gears, that mesh with a central fixed wheel gear so that, when the shafts of the arms rotate integral with the revolving support, the shafts are also rotated around their longitudinal axes, and opposite arms are rotated in opposite directions.
This solution provide a somewhat greater thrill, but it is still provided with some drawbacks, e.g. it is complex to produce, it has a rotating gear at the ground level (that may harm the users or passengers) and, during operation, causes the rotation of a great structure (i.e. the revolving support), so that it needs a great amount of energy to operate, due to the inertia of such a structure.
An object of the present invention is thus to provide an amusement device, providing a durable thrill and amusement to the user.
Another object of the present invention is to provide such an amusement device, in a simple and reliable manner.
A further object of the present invention is to provide such an amusement device, providing a safe experience to the user.
These and other objects are achieved by the present amusement device according to one or more of the appended claims. The present solution provides an amusement device according to claim 1. Additional features/aspects are presented in the dependent claims.
The amusement device according to the invention comprises:
The gear system is configured so that the angular speed (i.e. the magnitude of the angular velocity) of the arms is substantially identical for all the arms, and the first gear is directly meshing with the second gears, or it is coupled to the second gear via one or more secondary gears.
The first and second gears mesh directly, or via other gears, so that they can be placed with freedom in the amusement device. As a result, production and mounting of the amusement device is simple. Thanks to the present solution, the rotation of the arms can be operated independently from the rotation of the central shaft, thus providing energy saving, and also allowing to use motors of smaller dimension.
Preferably, the arms are arranged substantially perpendicularly with respect to the central shaft. More in general, considering the shaft axis (i.e. the longitudinal axis of the central shaft), the arm axes are distinct from the shaft axis.
According to a possible aspect, the central shaft comprises one or more movable portions, that are movable with respect to the base structure.
In particular, the central shaft comprises a portion that is rotatable with respect to the base structure, preferably by means of a shaft motor which is distinct from the gear motor.
According to a further aspect, the central shaft comprises a portion that is translatable with respect to the base structure, along a longitudinal axis of the central shaft.
Advantageously, having a portion that is translatable with respect to the base structure allows easy loading/unloading operation of the users on the vehicles, as a plurality of vehicles can be contemporarily placed at the ground level (or at the level needed to allow embarking of the users). In fact, in an exemplary embodiment of an amusement device according to the invention, the movable portion can be moved so that the vehicles of different arms come close to the ground (or to a platform allowing embarking and disembarking of the users) at the same time.
According to an aspect, the gear motor, the first gear and the second gears are mounted on one of the movable portions of the shaft. As an example, they can be mounted substantially at the top of the central shaft, so that they are distanced from the users, and from the arms. Also, the space occupied by the amusement device is reduced (in particular the footprint of the amusement device), as the motor is not placed laterally with respect to the central shaft.
According to an aspect the amusement device is configured so that for each arm, the path of one of the ends of the arm intersects the path of at least one end of another arm, and the gear system is configured to avoid collisions of the arms.
Advantageously, this provides entertainment to the user, which has the feeling that the vehicle of an arm (and in particular the vehicle on which he/she is seated) is going to collide with another vehicle of a different arm of the amusement device.
Also, during operation of the amusement device, the users are brought (in different times) near different vehicles, so that they visually interact with different users of the amusement device over time.
According to an aspect, the first gear is rotatable around a first gear axis and the second gears are rotatable around second gears axes, the first gear axis being perpendicular with respect to the second gear axes.
According to a further aspect, each of the second gears is coupled to a second gear shaft, the arms being coupled to the second gear shafts, or to arm shafts that is driven in rotation by, and parallel to, the gear shaft.
In a preferred embodiment, the amusement device according to the invention has an even number of arms, preferably four arms, so that a pair of opposite arms rotates around the same arm axis, along opposite direction, i.e. in a counterwise manner. According to an aspect, a first reduction stage is interposed between the gear motor and the first gear.
Furthermore, a second reduction stage can be interposed between the second gears and the relevant arms;
According to further aspect each arm is provided with a safety gear, configured so that:
The safety gears assure synchronization of the arms, even if one or more of the first/second gears is damaged, thus improving the safety of the users of the amusement device.
Preferably, the safety gears are provided with teeth that are arranged so that, in normal condition, the teeth of the safety gears do not mesh, while, in case of a failure, the teeth of a safety gear meshes with the teeth of at least one different safety gear, so that the latter may drive the former.
An aspect of the present invention also relates to a method of operation of an amusement device according to one or more of the preceding aspects, wherein the arms are rotated via the gear motor, and at least one movable portion of the central shaft is moved with respect to the base structure of the central shaft.
According to an aspect, the at least one movable portion comprises or consists of a translatable portion, that is translated with respect to said base structure.
In addition, or as an alternative solution, the at least one movable portion comprises or consists of a rotatable portion, that is rotated with respect to the base structure, preferably via a shaft motor operated independently from the gear motor.
A further aspect of the present invention relates to a method of operation of an amusement device according to one or more of the above discussed aspects, wherein each arm is provided with a safety gear, and when each of said arm is driven by the gear motor, the safety gear of an arm is disengaged from the safety gears of the other arms, and when there is a failure, and at least one of the arms is not driven by the gear motor, the safety gear of an arm that is not driven by the gear motor couples with the teeth of at least one safety gear of another arm.
One or more embodiments of the present invention are now described in greater detail with reference to the accompanying drawings provided by way of non-limiting example, wherein:
With reference to figures, the amusement device 1 comprises a central shaft 2, comprising a base structure 2a that, in use, is generally placed on the ground or, more in general, coupled to (or leaned on) an external surface.
The central shaft 2 has a longitudinal axis A1 that is typically vertical during use.
Preferably, the central shaft 2 comprises one or more portions 2b, 2c that are movable with respect to the base structure 2a. As an example, the portions 2b, 2c may be coupled in a nested tube arrangement, i.e. telescopically, with respect to the base structure 2a. In a preferred embodiment, shown in the figures, a first portion 2b of the central shaft 2 is translatable (typically in a slidable manner) with respect to the base structure 2a along the longitudinal axis A1 of the central shaft 2. A second portion 2c is integral in translation with the first portion 2b. In other words, when the first portion 2b translates with respect to the base structure 2a, the second portion 2c translates together with the first portion 2b. Further to that, the second portion 2c is rotatable with respect to the base structure 2a, around the longitudinal axis A1 of the central shaft 2.
In view of the above, the second portion 2c can rotate with respect to the base structure 2a and, via the first portion 2b, it can also be translated with respect to the base structure 2a.
The movable portions 2b, 2c are moved by means of known means 4a, 4b, 4c. As an example, as in the shown embodiment, one or more jacks 4a are used to translate the first movable portion 2b with respect to the base structure 2a. The movable portion 2c is moved by a shaft motor 4b mounted on the central shaft 2 which drives a shaft gear 4c. The shaft gear 4c is rotated to cause a rotation of the second movable portion 2c with respect to the base structure 2a.
As discussed, the shown embodiment is only a possible embodiment of a central shaft 2 provided with movable portions 2b, 2c. As an example, more than two translatable and telescopically arranged portions may be provided, in order achieve a longer run along the longitudinal axis of the central shaft 2. Also, the shown embodiment provides a first portion 2a that provides translation with respect to the base structure 2a, and a second portion 2c that provides rotation with respect to the base structure 2a. In different embodiments, not shown in detail, a single movable portion may be provided that is both translatable and rotatable with respect to the base structure 2a.
In addition, embodiments are possible where no translation or no rotation are provided, i.e. embodiments comprising only movable portions of the central shaft that are translatable with respect to the base structure, and also embodiments only comprising movable portions that are rotatable with respect to the base structure of the central shaft.
Finally, an amusement device according to an embodiment of the present invention can be provided with a central shaft having no movable portions, i.e. with a central shaft that is substantially wholly integral with respect to the ground (or the surface to which the shaft is coupled).
A plurality of arms 3a, 3b, 3c, 3d are coupled to the central shaft 2. As mentioned, the central shaft is preferably provided with a plurality of movable portions 2b, 2c. The arms 3a-3d are thus preferably coupled to the movable portions 2b, 2c of the central shaft 2. According to an aspect, the arms 3a-3d are coupled to the portion 2c that is both translatable and rotatable with respect to the base structure 2a. In the shown embodiment, the arms 3a-3d are coupled to the second portion 2c that, as mentioned, is rotatable with respect to the base structure 2a and (thanks to the coupling with the first portion 2b) is also translatable along the longitudinal axis A1 of the central shaft 2.
Each arm 3a-3d is coupled to the central shaft 2 in a rotatable manner, around an arm axis A2, that is angled, preferably in a perpendicular manner, with respect to the longitudinal axis A1 of the central shaft 2. Preferably, all the arm axes A2 lie on the same plane. Each arm 3a-3d is typically coupled to the central shaft 2 by means of a shaft arm 5, that is arranged perpendicularly with respect to the central shaft 2.
The arms 3a-3d carry one or more vehicles 6, having a plurality of seats 6a for the users of the amusement device 1. The vehicles 6 are preferably placed at the ends 31, 32 of the arms 3a-3d. According to an aspect, the arms 3a-3d carry at least one vehicle 6 per each end 31, 32 of the arm. The ends 31, 32 of an arm 3a-3d are the two areas of the arms 3a-3d placed at the greatest distance from the relevant arm axis A2.
According to an aspect, the vehicles 6 are hinged to the arms 3a-3d so that the seats are maintained in a substantially vertical manner during operation of the amusement device 1, i.e. the users are not turned upside down during rotation of the arms 3a-3d. The number of arms 3a-3d may vary in different embodiments. Preferably, the amusement device 1 is provided with an even number of arms 3a-3d, more preferably four arms 3a-3d, as per the shown embodiment. Preferably, the angle between two subsequent arms is equal, i.e. the arms 3a-3d are angled with respect to each other at an angle that is substantially equal to 360°/n, where n is the number of arms. Such an angle is measured in plant view. In the shown embodiment, there are four arms, that are disposed at 90 degrees with respect to each other. According to an aspect, couples of opposite arms substantially share the same arm axes A2. As an example, in the shown (preferred) embodiment, there are four arms 3a-3d, and two arm axes A2. Arms 3a and 3c share the same arm axis. Similarly arms 3b and 3d share a second arm axis. Even if some of the arms 3a-3d share the same arm axis A2, the arm shafts 5 are distinct one from the other, i.e. there is a single and distinct arm shaft 5 for each arm 3a-3d. Due to this fact, there may be a minimum difference, due to tolerances, between the orientation arm axes A2 of opposite arms. However, such a minimum difference, due to previously mentioned tolerances, fall within the definition of “substantially sharing the same arm axis”.
Opposite arms (such as arms 3a and 3c, or 3b and 3d of the shown embodiments) rotate in opposite direction, i.e. in a counterwise manner. In other words, the arm shafts 5 of opposite arms rotate in a counterwise manner. Thus, considering a common arm axis A2, one arm rotates in a clockwise manner, while the other opposite arm rotates in a counter-clockwise manner.
During rotation of the arms 3a-3d, the ends 31, 32 of each arm 3a-3d moves along a path P1-P4 (shown schematically in
In other words, a path of a first arm intersects with the path of a second arm, if there is at least one point of the space that, during use, is occupied (in different times) by both the first arm and the second arm.
Typically, the path of one end of each arm intersects with the path of two different arms. As an example, as schematically shown in
According to an aspect, the arms 3a-3d are substantially symmetrical with respect to the arm axis A2, so that the path of the two ends 31, 32 of the same arm 3a-3d coincide.
Preferably, for each arm 3a-3d, the path of the vehicle 6 of an arm intersects (i.e. overlaps) with the path of the vehicle 6 of a different arm. In view of the above, the path of two vehicles of different arm intersect if there is at least a point (typically a volume) of space that, during operation of the amusement device 1, is occupied, in different times, by both the vehicles. In other words, during operation of the amusement device, there is at least a position of a vehicle of an arm that was previously, at least partially, occupied by the vehicle of a different arm.
This provides to the user the feeling that the vehicle 6 of an arm 3a-3d (and in particular the vehicle on which he/she is seated) is going to collide with another vehicle 6 of a different arm 3a-3d of the amusement device. The amusement device 1 is however configured so that the arms 3a-3d never collide one with the other, i.e. the movements of the arms 3a-3d are synchronized to avoid collisions between the arms 3a-3d.
First of all, the arms 3a-3d are rotated at the same angular speed. In other words, at a given time, during operation of the amusement device 1, all the arms 3a-3d have the same angular speed. The angular speed of one arm may be varied over time. If this happens, all the other arms behave in a same manner. In other words, if at a given time arm 3a is rotated at a first angular speed, all the other arms 3b-3d are rotated at the same first angular speed. If, in a following moment, arm 3a is rotated at a second angular speed, e.g. greater than the first one, all the other arms 3b-3d are rotated at such a second angular speed.
The amusement device 1 comprises a gear system 7 to synchronize the movement (i.e. the rotation) of the arms 3a-3d.
The gear system 7 comprises a gear motor M and a plurality of gears 71-74b. In particular, the gear motor M is configured to rotate a first gear 71, that in turn rotates a plurality of second gears 72a-72d.
The first gear 71 and the second gears 72a-72d are typically gear wheels. In the schematic view of
The gear motor M may be any known motor, in particular it may be an electric motor known in the art, that is configured to rotate a relevant drive shaft. The first gear 71 may be directly mounted on the drive shaft or, more preferably, as per the shown embodiment, it can be coupled to the gear motor M via a first reduction stage 73. In other words, the gear motor M drives the first reduction stage 73, that in turn drives the first gear 71.
The second gears 72a-72d are coupled to the arms 3a-3d, so that rotation of the second gears 72a-72 causes a rotation of the arms 3a-3d. As a result, there is a second gear 72a-72d for each of the arms 3a-3d. According to a possible embodiment, the second gears 72a-72d are coupled to a gear shaft that coincide with the arm shaft 5. However, according preferred embodiments, as the one shown in the figures, the second gears 72a-72d are coupled to gear shafts 720 that are distinct from the arm shafts 5.
Preferably, there is a second reduction stage 74a, 74b between the second gears 72a-72d and the arms shafts 5. In the shown embodiment, the second reduction stage 74a, 74b comprises, for each arm 5 of the arms 3a-3d, a first gear wheel 74a coupled to the gear shaft 720, that meshes with a relevant gear wheel 74b having greater diameter with respect to the first gear wheel 74a, and that is coupled to the arm shaft 5.
According to an aspect, the gear shafts 720 are not made in one piece; in fact, the gear shafts 720 preferably comprise at least two portions 720a, 720b that are coupled via a flexible joint 720c, known in the art, to reduce the loads on the gear shafts 720.
Preferably, the gear shafts 720 are supported by a frame 722 which, in a possible embodiment, has a substantially square shape, i.e. it has the shape of a substantially square picture shape. In other words, the frame 722 is provided with four plates arranged along the sides of a square. Preferably each gear shaft 720 is attached to said frame 722 by means of support blocks 723a, 723b, 723c, 723d.
According to an aspect, said support blocks 723a-723d are positioned in correspondence of the vertexes of shape defined by the frame 722.
The coupling between the gear shafts 720 and the frame 722 allows to assure that the relevant position between the gear shafts is maintained over time. As an example, in the shown embodiment, the gears shafts 720 are maintained, over time, substantially perpendicularly one to the other via the frame 722.
According to an aspect, the first gear 71 meshes directly with all the second gears 72a-72d, as shown in the figures. However, embodiments are possible where further secondary gears, preferably gear wheels, are placed between the first gear 71 and the second gears 72a-72d. As an example, the first gear 71 may mesh with a secondary gear, that in turn meshes with the second gears 72a-72d.
Preferably, the first gear 71 rotates around a first gear axis 710 that is perpendicular to the second gear axes 721a-721d (that are the axes around which the second gears 72a-72d rotate). Typically, the first gear axis 710 is parallel (and preferably substantially coincident) with the longitudinal axis A1 of the central shaft 2, while the second gear axes 721a-721d are substantially parallel to the arm axes A2. Preferably, the second gear axes 721a-721d lie on the same plane. Preferably, the gear motor M, the first gear 71 and the second gears 72a-72d are coupled to the central shaft 2, preferably at a portion of the first shaft 2 that is distal with respect to the base structure 2a.
As mentioned, the central shaft 2 is typically provided with one or more movable portions 2b, 2c. The motor M, the first gear 71 and the second gears 72a-72d are thus preferably coupled to a movable portion 2c of the central shaft 2.
It has to be noted that the gear motor M is a distinct and independent element with respect to the means that move the movable portions 2b, 2c of the central shaft 2 with respect to the base portion.
According to a preferred embodiment, shown in the figures, the amusement device 1 is provided with a plurality of safety gear 75a-75d. In more detail, a preferred embodiment is provided with a safety gear 75a-75d for each arm 3a-3d.
The safety gears 75a-75d are configured so that, when all the arms 3a-3d are driven by the gear motor M, the safety gears 75a-75d are disengaged from one another, and they do not touch each other. In other words, none of the safety gears drives another safety gear. In case of a failure, at least a first safety gear 75a-75d is coupled to a second safety gear 75a-75d, so that a second safety gear may drive the first safety gear. Preferably, the safety gears are mounted onto the arm shafts 5, so that they rotate together with the arm shafts 5. In particular, at least during a failure, more preferably in all the operating conditions of the amusement device 1, the rotation of the safety gears 75a-75d is integral with the rotation of the arms 3a-3d around the relevant arm axes A2. Thus, in case of a failure, e.g. a mechanical failure in the gear system 7, one or more safety gears 75a-75d may be coupled to a different safety gear 75a-75d, so that the synchronization of the arm shafts 5 is not lost.
According to a preferred aspect, the safety gears 75a-75d are provided with teeth 751 that are arrange so that, during normal operation of the amusement device 1, the teeth 751 of a safety gear 75a-75d do not mesh with the teeth of another safety gear 75a-75d, while they are brought into contact in case of need. Preferably, during normal operation of the amusement device 1, the teeth of a safety gear 75a-75d pass within the space between subsequent teeth 751 of at least another gear 75a-75d, without touching them. In such an embodiment, the space between subsequent teeth is greater than the width of the teeth 751.
In use, the amusement device 1 is placed in a loading position, to allow the users of the amusement device 1 to embark on the vehicles 6 (and possibly to allow the users of the previous ride to disembark the vehicle 6). As discussed, the central shaft 2 is preferably provided with a translatable portion 2b. In a first step the movable portion 2b is translated, e.g. by means of one or more jacks 4a, with respect to the base structure 2a, moving the vehicles towards the ground, or to a relevant external surface/platform. As mentioned, the central shaft 2 is typically arranged (in use) in a vertical position, so that in this step the movable portion 2b is lowered along the vertical direction. The arms 3a-3d are rotated until one of the ends 31, 32 of each arm 3a-3d comes close to the ground/platform on which the users are waiting, allowing the embarking/disembarking of users on/from the at least one vehicle 6, and preferably at least one vehicle 6 of each arm 3a-3d is placed in a position allowing the users to embark such a vehicle. According to an aspect, in the above discussed loading/unloading position, the arms 3a-3d can be angled with respect to the horizontal (i.e. it has an angle greater than 0° and less than 90°), to allow different users to embark on vehicles placed on different arms. Preferably, the arms 3a-3d form an angle of about 45° with respect to the horizontal, as shown in
Typically, after this step, only the vehicles placed at one end 31, 32 of the arms 3a-3d are loaded with users.
Thus, in a following step, the arms 3a-3d are rotated, typically by 180°, allowing the users to be loaded also in the remaining vehicles, placed at the oppose ends of the arms with respect to the ones that were loaded in the preceding step.
Preferably, to carry out this step, the movable portion 2b is first raised to allow rotation of the arms, and then lowered again to allow embarking of the users, in a manner similar to the previously discussed step.
A different embodiment of the present invention may e.g. provide raised platform arranged laterally to the amusement device 1, allowing the users to embark/disembark on an amusement device 1 that is not provided with a translatable portion 2b.
Also, it is not excluded that the users are loaded in more than two steps, e.g. because the amusement device 1 is provided with a plurality of arms, or because the arms 3a-3d are placed in subsequent angular position that do not allow the user to embark on vehicles of all the arms of the amusement device 1.
In any case, preferred embodiments of the invention, as the one shown in the figure, allow to embark/disembark the users in only two steps, a first steps where part of the users are loaded on the vehicles of a first end 31, 32 of all the arms 3a-3d, and a second step where the remaining users are loaded in all the remaining vehicles 6, i.e. the vehicles placed at the opposite end with respect to the ones of the first step.
At the end of the loading/unloading, i.e. when all the users are loaded/unloaded on/from the vehicles 6, the gear motor M is operated to cause rotation of the arms 3a-3d, in order to start the ride of the amusement device 1. Preferably, the movable portion 2b is translated with respect to the base structure 2a, typically is raised along the longitudinal axis A1 of the central shaft, as shown in
During operation of the amusement device 1, the movable portions 2b, 2c of the central shaft 2 can be moved with respect to the base structure 2a, to improve the feeling of the users. As an example, the rotatable portion 2c can be rotated, e.g. via the shaft motor 4b to cause the rotation of the vehicles around the central axis A1 of the central shaft 2. in addition, or as an alternative, the translatable portion 2b can be translated along the central axis A1 of the central shaft 2.
As above discussed, the arms 3a-3d are rotated by the gear system 7 which allows to synchronize the movement of the arms 3a-3d.
In particular, according to a preferred embodiment, the gear motor M is configured to rotate a first gear 71, that in turn rotates a plurality of second gears 72a-72d which are coupled to the respective gear shafts 720, which in turn are coupled to the arms 3a-3d, so that rotation of the second gears 72a-72 causes a rotation of the arms 3a-3d.
Typically, adjacent arms (such as arms 3a and 3b, or 3b and 3c of the shown embodiments) rotate in opposite direction, i.e. in a counterwise manner. Also, if the amusement device 1 is provided with arms that are opposite one to the other, i.e. if the amusement device 1 is provided with one or more couples of arms 3a-3d sharing a common arm axis A2, the arms rotate in opposite direction with respect to such a common axis (such as arms 3a and 3d, or 3b and 3d of the shown embodiments) one arm rotates in a clockwise manner, while the other opposite arm rotate in a counter-clockwise manner with respect to such a common arm axis A2.
During rotation, the ends 31, 32 and relative vehicles 6 of each arm 3a-3d moves along a path, typically a circular path. According to a preferred aspect, for each arm, the path of a first end of an arm intersects the path of an end of a different arm, according to the meaning of the “intersection” above discussed.
Thanks to the gear system 7, the arms 3a-3d never collide one with the other, i.e. the movements of the arms 3a-3d are synchronized to avoid collisions and harm to the users of the amusement device 1.
At the end of the ride, the shaft motor 4b is stopped and the unloading operation takes place, in a manner similar to what was disclosed for the loading step, i.e. by placing the vehicles 6 in subsequent steps near to the ground, or to a relevant platform.
In case of malfunctioning, safety gears 75a-75d are preferably provided to maintain the synchronization of the rotation of arms 3a-3d around the relevant arm axes A2. As an example, considering the safety gear 75a, during normal operation of the amusement device 1, the safety gear 75a is disengaged from the other safety gears 75b-75d. Preferably, teeth 751 of safety gear 75a are disengaged from (i.e. do not mesh with) the teeth 751 of safety gears 75a-75d, e.g. they pass between the spaces of the teeth 751 of safety gears 75b and 75d, without touching them. As a result, in this condition, the safety gears 75a-75d do not provide a particular effect.
However, in case of malfunctioning, an arm 3a-3d may no more be rotated by the gear motor M, e.g. due to wear of the relevant second gear. For easiness of description, it will be now be discussed malfunctioning of the arm 3a, but the following discussion applies to the other arms 3b-3d as well.
In particular, if e.g. there is an excessive wear of the second gear 72a, the arm 3a may not be rotated by the gear motor M. Without the safety gears 75a-75, the arm 3a would crash against arm 3b and/or arm 3c. On the contrary, thanks to the present solution, the safety gear 75a, in first (very short) moment, i.e. when the malfunctioning occurs, loses its synchronization with the other safety gears 75b-75c. In particular, with reference to the shown preferred embodiment, the teeth of the safety gear 75a do not fall anymore within the space between the teeth 751 of the safety gears 75b and 75c, but the they contact the teeth of the safety gears 75b and/or 75c. As a consequence, the safety gear 75a meshes with the safety gear 75b and/or with the safety gear 75c, according to the sense of rotation of the gear system 7.
More in general, the safety gear 75a is driven in rotation by safety gear 75b and/or safety gear 75c.
As a consequence, the arm 3a is still rotated by the gear system 7 via the coupling (e.g. via relevant meshing) of the safety gear 75a with safety gears 75b and 75c, even if the coupling between the first gear 71 and the second gear 72a is broken.
It should be noted that the safety gears 75a-75d may compensate for even more than one failure in the gear system. As an example, only one arm may be properly coupled to the motor M, and the amusement device would still operate in a substantial proper manner. As an example, second gear 72a-72c may be broken, so that only second gear 72d is still rotatably coupled to the first gear 71. Even in this case, the relevant safety gear 75d would drive safety gears 75b and 75c that, in turn, would drive the last safety gear 75a, allowing the amusement device 1 to continue its run.
Finally, it may be the case that none of the second gears 72a-72d is properly coupled to the motor, e.g. due to a break in the first gear 71. Even in this case, the safety gears 75a-75d assure a synchronization of the movement of the relevant arms 3a-3d. In fact, the motor M would drive none of the arms 3a-3d. As a result, all the safety gears 75a-75d are coupled, continuing the run of the arms 3a-3d due to inertia, until they stop. As above discussed, meshing of the safety gears 75a-75d assure synchronization of the arms 3a-3d, for the whole time of rotation of the arms 3a-3d, avoiding collisions between the vehicles 6 of the amusement device 1.
Number | Date | Country | Kind |
---|---|---|---|
18205541 | Nov 2018 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2019/080720 | 11/8/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/094854 | 5/14/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2255175 | Lorow | Sep 1941 | A |
8926440 | Jacobi | Jan 2015 | B2 |
20060035715 | Threlkel | Feb 2006 | A1 |
20080113822 | Kitchen | May 2008 | A1 |
Number | Date | Country |
---|---|---|
102814044 | Dec 2012 | CN |
288244 | Mar 1909 | DE |
17873 | Feb 1908 | GB |
238809 | Aug 1925 | GB |
Entry |
---|
International Search report and written opinion issued by the EPO dated Dec. 5, 2019 for PCT/EP2019/080720. |
Office Action issued by the CN patent office for corresponding CN application No. 201980009196.1 dated Apr. 14, 2021. |
Number | Date | Country | |
---|---|---|---|
20210402311 A1 | Dec 2021 | US |