JP6121636B2 - Yo-yo ball with friction kinetic energy storage and acceleration function - Google Patents

Description

  The present invention relates to a yo-yo ball, and more particularly, to a yo-yo ball having a friction kinetic energy storage and acceleration function.

  In the current market, a yo-yo ball consists essentially of two rotating bodies and a connecting shaft connecting the two rotating bodies, so that a string is wound around the center of the two rotating bodies. The yo-yo ball body is thrown down with great force so that it can rapidly rotate at the end of the string. However, limited by the yo-yo ball return system and bearing system, a short user cannot play by throwing the yo-yo ball body down with a string. This is because the length of the string is proportional to the height of the user's back. For a tall user, after the ball body is thrown down, there is an acceleration region sufficient to accelerate the ball body to a certain speed, which can lead to various acrobatics. On the other hand, a short player cannot move the ball. This is because the acceleration area after the ball is thrown down is too short, and the rotation speed of the ball is not sufficiently high.

  It is an object of the present invention to solve the above problems and to provide a yo-yo ball having a friction kinetic energy storage and acceleration function that can store energy by a well-designed and extremely interesting manual operation.

  The technical solution of the present invention will be implemented as follows.

  In a yo-yo ball having a frictional kinetic energy storage and acceleration function that includes two rotating bodies and a connecting shaft that connects the two rotating bodies, each of the rotating bodies includes a disk body and a side cover. Each of the disk bodies is rotatable with respect to the cover, and a friction kinetic energy storage mechanism is provided therein, and one end of the friction kinetic energy storage mechanism is connected to the disk body, and the other end. Is connected to the side cover, and by picking the side covers of the two rotating bodies, the disk body is brought into contact with the external contact surface, and the frictional kinetic energy storage mechanism stores energy by friction rolling, thereby storing the energy. After that, the frictional kinetic energy storage mechanism is energized by removing the disc body from contact with the external contact surface. Releasing the, has two disk members to be driven to rotate synchronously in a direction opposite to the rolling direction.

  In order to reduce unnecessary energy loss released by the frictional kinetic energy storage mechanism, according to the present invention, each of the disk bodies is provided with a direction limiting mechanism inside thereof, and the direction limiting mechanism is The cover is arranged at a position to be connected to the frictional kinetic energy storage mechanism, one end of the direction limiting mechanism is connected to the side cover, and the other end is connected to the frictional kinetic energy storage mechanism to limit the direction. The direction of rotation limited by the mechanism is the same as the energy storage direction of the frictional kinetic energy storage mechanism, and by picking the side covers of the two rotating bodies, the disk body is brought into contact with the external contact surface, and the direction limiting mechanism The frictional kinetic energy storage mechanism stores energy by friction rolling toward the rotation direction limited by

  In order to prevent the overload energy storage from damaging the frictional kinetic energy storage mechanism, according to the present invention, each of the disk bodies is provided with an overload protection mechanism inside, and the overload protection mechanism is The cover is arranged at a position where it is connected to the friction kinetic energy storage mechanism, one end of the overload protection mechanism is connected to the side cover, and the other end is connected to the friction kinetic energy storage mechanism, When the overload energy storage for the frictional motion protection mechanism is performed by picking the cover, the side cover is detached from the frictional kinetic energy storage mechanism by the action of the overload protection mechanism, and thereby the energy for the frictional motion energy storage mechanism is reduced. Storage is to be stopped.

  In order to reduce unnecessary energy loss released by the frictional kinetic energy storage mechanism and prevent overload energy storage from damaging the frictional kinetic energy storage mechanism, according to the present invention, any of the disk bodies can be A direction limiting mechanism and an overload protection mechanism are provided inside, and the direction limiting mechanism and the overload protection mechanism are arranged at a position where the side cover is connected to the frictional kinetic energy storage mechanism, and one end of the direction limiting mechanism. Is connected to the frictional kinetic energy storage mechanism, the other end is connected to one end of the overload protection mechanism, the other end of the overload protection mechanism is connected to the side cover, The restricted rotation direction is the same as the energy storage direction of the frictional kinetic energy storage mechanism. The disc body is brought into contact with the external contact surface, and the frictional kinetic energy storage mechanism stores energy by friction rolling in the rotational direction limited by the direction limiting mechanism, and the overload energy for the frictional kinetic energy storage mechanism is stored. When the storage is performed, the side cover is detached from the direction limiting mechanism by the action of the overload protection mechanism, whereby the energy storage for the frictional kinetic energy storage mechanism is stopped.

  The direction limiting mechanism may have many structural forms, and the direction limiting mechanism in the present invention includes a plurality of direction limiting blocks, a mounting disk on which all of the direction limiting blocks are mounted, and an inner helical gear tooth. The direction-restricting block is connected to the bottom surface of the mounting disk by a pin bolt so as to be automatically rotated, and protrudes above the mounting disk. And the gear disc is placed over the direction limit block so that the limit pawl of the direction limit block clamps in one direction to the inner helical gear teeth and rotates the gear disc in one direction. One end of the friction kinetic energy storage mechanism is connected to the gear disc, and the overload protection mechanism is mounted It is connected to the disk.

  In order to reduce the number of parts as much as possible, the overload protection mechanism is provided with a circular ring, convex teeth are provided on the arc surface of the circular ring, and the inner gear ring is convex teeth. The inner gear ring is arranged on the upper surface of the mounting disc and is provided with a long convex key in the center of the circular ring, correspondingly with a long convex key on the side cover When a long keyway that is connected to fit is provided and overload energy storage is performed for the frictional kinetic energy storage mechanism, the circular ring is deformed under stress and the convex teeth are detached from the inner gear ring Thus, the direction limiting mechanism and the frictional kinetic energy storage mechanism rotate together with the disk body, and the frictional kinetic energy storage mechanism stops the energy storage.

  The energy storage mechanism of the present invention includes an energy storage spring and a spring case, the energy storage spring is disposed in the spring case, and an outer end of the energy storage spring is clamped and connected to the spring case. The inner end of the energy storage spring is clamped and connected to the direction limiting mechanism, the energy storage rotation direction of the energy storage spring is the same as the rotation direction limited by the direction limiting mechanism, and the spring case is It is fixed and connected to the disc body.

  Further, a through hole is formed in the center of the spring case, and an ear is provided in the lower part of the gear disc. The ear enters the spring case through the through hole. A plurality of arc pieces distributed apart from each other are provided along the circumference of the part, a gap is maintained between the arc piece and the ear part, and a hook is provided at the lower end of the arc piece. After the ears of the gear disk are inserted into the through holes of the spring case, the hooks are extended out of the through holes and fixed to the side parts of the through holes, so that the gear disks are connected to the spring case. The inner end of the energy storage spring is clamped and connected to the arc piece of the gear disk.

  In order to improve the smooth performance of the rotation of the disc body, a bearing stand is provided in the center of the gear disc, a bearing is mounted on it, and the connecting shaft is inserted into the bearing hole and connected Yes.

  In order to prevent the disc body from being damaged by frequent friction and to avoid the difficulty of storing energy due to friction due to the low coefficient of friction of the disc body, the disc edge of the disc body is attached to the friction ring. The friction ring is connected to and connected to the disk body by a screw, the diameter of the friction ring is larger than the disk mouth diameter of the disk body, and the side cover is a friction ring And is connected to the connecting shaft by bolts.

  According to the present invention, each of the disk bodies of the rotating body is provided with a friction kinetic energy storage mechanism therein, one end of the friction kinetic energy storage mechanism is connected to the disk body, and the other end is It is connected to the side cover, and by picking the side cover of the two rotating bodies, the disk body is brought into contact with the external contact surface, and the friction kinetic energy storage mechanism stores energy by friction rolling. . After the energy storage, when the disk body is removed from contact with the external contact surface, the frictional kinetic energy storage mechanism releases the energy so that the two disk bodies rotate synchronously in the direction opposite to the rolling direction. When it is driven and the side cover is released at the same time, the entire yo-yo ball body rotates. Thus, the yoyopole body can be rotated without throwing the yoyoball body with the string. Even if the string is too short, the ball body can rotate at high speed after throwing down, and this high speed rotation is not affected by the acceleration area after the ball body is thrown down. Therefore, even a short player can enjoy the play of the yo-yo ball to the maximum and bring about various acrobatics. The demands of players of different ages and heights will be met. Compared with existing yo-yo balls, this yo-yo ball with friction kinetic energy storage and acceleration function expands new operation modes and new playing methods, makes it more interesting and diversifies playing methods Can do. In addition, each of the disc bodies is provided with a direction limiting mechanism and an overload protection mechanism inside thereof, thereby reducing unnecessary energy loss released by the frictional kinetic energy storage mechanism, The rotation time can be effectively improved, the frictional kinetic energy storage mechanism can be prevented from being damaged by the overload energy storage, and the life of the yo-yo ball can be effectively extended. The disk port of the disk body is connected to a friction ring, and the diameter of the friction ring is larger than the disk port diameter of the disk body. Thus, during energy storage due to friction, contact friction occurs between the friction ring and the contact surface, and the disk body is well protected from friction and damage, thereby further extending the life of the yo-yo ball. Since the friction coefficient of the friction ring is large, the friction ring does not slip during rolling friction, and the energy storage effect is improved. If the energy storage effect is reduced, only the friction ring need be replaced. This yo-yo ball is cleverly designed and not only fulfills the requirements for the entertainment of short users, but also expands the way of playing yo-yo balls and is extremely interesting, Satisfying the exploration of new things, giving players plenty of room to imagine how to play and making yo-yo balls attractive to players over time.

  Hereinafter, the present invention will be further described with reference to the accompanying drawings.

It is a three-dimensional schematic structure diagram of the present invention. 1 is a schematic cross-sectional view of the present invention. 1 is a schematic exploded view of the present invention. FIG. 3 is a schematic exploded view of a side cover, an overload protection mechanism, and a direction limiting mechanism of the present invention.

  As shown in FIGS. 1 to 4, the yo-yo ball having a frictional kinetic energy storage and acceleration function includes two rotating bodies 1 and a connecting shaft 2 that connects the two rotating bodies 1. Each of the rotating bodies 1 includes a disk body 11 and a side cover 12, and the disk body 11 is rotatable with respect to the side cover 12. Each of the disk bodies 11 is provided with a frictional kinetic energy storage mechanism 3 therein. One end of the frictional kinetic energy storage mechanism 3 is connected to the disk body 11, and the other end is connected to the side cover 12. By picking the side covers 12 of the two rotating bodies 1, the disk body 11 is brought into contact with the external contact surface, and energy is stored in the frictional kinetic energy storage mechanism 3 by friction rolling. After energy storage, the disc body 11 is removed from contact with the external contact surface, so that the frictional kinetic energy storage mechanism 3 releases the energy, and the two disc bodies 11 are synchronously rotated in the direction opposite to the rolling direction. When the side cover 12 is released at the same time, the entire yo-yo ball body rotates. Thus, the yoyopole body can be rotated without throwing the yoyoball body with the string. Even if the string is too short, the ball body can rotate at high speed after being thrown down, and this high speed rotation is not affected by the acceleration region after the ball body is thrown down. Therefore, even a short player can enjoy the play of the yo-yo ball to the maximum and bring about various acrobatics. The demands of players of different ages and heights will be met. Compared with existing yo-yo balls, this yo-yo ball with friction kinetic energy storage and acceleration function expands new operation modes and new playing methods, makes it more interesting and diversifies playing methods Can do.

  As shown in FIG. 3, in this embodiment, the disk body 11 is provided with a direction limiting mechanism 4 and an overload protection mechanism 5 inside thereof. These mechanisms 4 and 5 are arranged at positions where the side cover 12 is connected to the frictional kinetic energy storage mechanism 3. The direction restriction mechanism 4 in this embodiment includes four direction restriction blocks 41, a mounting disk 42 to which all of the direction restriction blocks 41 are attached, a gear disk 43 in which inner spiral gear teeth 431 are provided in a concave shape, It has. Four pin holes 421 are provided on the bottom surface of the mounting disk 42, and the direction limiting block 41 is inserted into the pin hole 421 by the pin bolt 9. As a result, the direction restricting block 41 is connected to the bottom surface of the mounting disk 42 so as to be automatically rotated, and protrudes above the mounting disk 42. The gear disk 43 is placed on the direction restricting block 41, whereby the restricting claw of the direction restricting block 41 is clamped to the inner helical gear teeth 431. Therefore, when the gear disc 43 rotates opposite the direction of the direction limiting block 41, the limiting pawl is clamped to the inner helical gear teeth 431, so that the gear disc 43 cannot rotate, thereby Thus, the unidirectional rotation of the gear disk 43 is realized. The gear disk 43 of the direction limiting mechanism 4 is connected to one end of the frictional kinetic energy storage mechanism 3. The overload protection mechanism 5 of this embodiment includes a circular ring 51. Convex teeth 511 are provided on the circular arc surface of the circular ring 51 in a convex shape. An inner gear ring 52 is engaged with the convex teeth 511. The inner gear ring 52 is disposed on the upper surface of the mounting disk 42. That is, the mounting disk 42 and the inner gear ring 52 are integrally designed, thereby reducing the number of parts, reducing costs, and making the structure smaller. A long convex key 512 is provided at the center of the circular ring 51, and a long key groove 121 corresponding to the long convex key 512 and connected to the side cover 12 is provided correspondingly. A total of three convex teeth 511 are provided on the circular ring 51. When overload energy storage is performed on the frictional kinetic energy storage mechanism 3, that is, when friction rolling is basically impossible, if the user continues to force friction rolling, the circular ring 51 applies stress. In response to the deformation, the convex teeth 511 are detached from the inner gear ring 52. As a result, the side cover 12 cannot restrict the mounting disk 42, and the entire direction limiting mechanism 3 is in a detached state and rotates together with the disk body 11, thereby the energy storage of the frictional kinetic energy storage mechanism 3. Will be stopped.

  As shown in FIGS. 2 and 3, the energy storage mechanism 3 of this embodiment includes an energy storage spring 31 and a spring case 32. The energy storage spring 31 is a spiral spring. The spiral spring is disposed in the spring case 32, and the outer end thereof is fixed to the spring case 32. The spring case 32 includes a case body 322 and a cover body 321. A notch 323 is formed at the edge of the case body 322, and the outer end of the energy storage spring 31 is fixedly connected to the notch 323. Three perforated ears 324 are provided along the periphery of the cover body 321. After the cover body 321 is put on the case body 322, the cover body 321 and the case body 322 are aligned straight with each other by the hole of the ear portion 324 and the screw hole of the disk body 11, and are connected and fixed by screws. It is like that. A through hole 320 is formed in the center of the spring case 32. Correspondingly, an ear 430 is provided in the lower part of the gear disk 43 of the direction limiting mechanism 4. The ear portion 430 enters the spring case 32 through the through hole 320. Three arc pieces 432 distributed apart from each other are provided along the periphery of the ear portion 430, and a gap is maintained between the arc piece 432 and the ear portion 430. A hook 433 is provided at the lower end of each arc piece 432. After the ear portion 430 of the gear disc 43 is inserted into the through hole 320 of the spring case 32, the hook 433 is extended out of the through hole 320 and fixed to the side portion of the through hole, whereby the gear disc 43 is fixed to the spring case. 32 will be connected. The inner end of the energy storage spring 31 is clamped and connected to the arc piece 432 of the gear disk 43. A bearing base 434 is provided at the center of the gear disk 43, and the bearing 6 is mounted thereon. The connection shaft 2 is inserted into and connected to the central hole of the bearing 6. The disc edge of the disc body 11 of this embodiment is connected to the friction ring 7. The friction coefficient of the friction ring 7 is larger than the friction coefficient of the disk body 11. The friction ring 7 is provided with a countersunk hole, and a screw passes through the countersunk hole and is screwed into a screw hole at the disk lip of the disk body 11, thereby achieving a locking connection. The diameter of the friction ring 7 is larger than the diameter of the disk port of the disk body 11, thereby causing contact friction between the friction ring 7 and the contact surface during energy storage by friction. The disk body 11 is well protected from friction and damage, thereby further extending the life of the yo-yo ball. Since the friction coefficient of the friction ring 7 is large, the friction ring 7 does not slip during rolling friction, and the energy storage effect is improved. If the energy storage effect is reduced, only the friction ring 7 needs to be replaced. In addition, a decorative ring edge 8 is fitted near the edge of the outer surface of the friction ring 7. An arcuate convex rib 81 is provided downward on the decorative ring edge 8, and an arcuate elongated hole 71 is provided in the friction ring 7 correspondingly. An arc-shaped convex rib 81 is inserted into the arc-shaped long hole 71, whereby the decorative ring edge 8 is fixed to the friction ring 7.

  As shown in FIG. 4, the side cover 12 of this embodiment covers the outer surface of the friction ring 7. A countersink 122 is formed in the center of the side cover 12. A circular hole 513 is provided at the center of the long convex key 512 of the circular ring 51, and a long key groove 514 smaller than the long convex key 512 is provided in a concave shape at the bottom of the long convex key 412. In this embodiment, through holes are provided in the center of the mounting disk 42 and the center of the ear portion 430 of the gear disk 43, and the connecting shaft passes through the through hole. In this embodiment, the end of the connecting shaft 2 is designed to be a long convex key 21 that fits into a long keyway 514 at the bottom of the circular ring 51. A screw hole 22 is provided in the center of the long convex key 21. After the connection shaft 2 passes through the through holes of the attachment disk 42 and the gear disk 43, the long convex key 21 at the end of the connection shaft 2 is inserted into the long key groove 514 of the circular ring 51, and the side cover 12 A bolt that penetrates the countersink 122 of the side cover 12 and the circular hole 513 of the circular ring 51 from the outside is screwed into the screw hole 22 of the connection shaft 2 as shown in FIG. In addition, the main bearing is disposed between the two rotating bodies 1 of the yo-yo ball of this embodiment, and the string of the yo-yo ball is wound around the main bearing.

  How to play yo-yo balls is as follows.

  Wrap a string around the yo-yo ball, pick the side covers 12 on both sides of the yo-yo ball body, then place the yo-yo ball on a desk, the ground, or other external contact surface, and bring the friction ring 7 into contact with the contact surface; Roll in one direction. If it rolls forward easily without much resistance, this means that the rolling direction is not the direction of storing energy for the frictional kinetic energy storage mechanism 3. The reason why there is no rolling resistance is that the gear disk 43 of the direction limiting mechanism 4 is not limited by the direction limiting block 41. That is, the gear disk 43 rotates with respect to the side cover 12. In other words, the gear disk 43, the energy storage spring 31, and the spring case 32 rotate synchronously with the rolling of the disk body 11, so that energy cannot be stored in the energy storage spring 31. Therefore, it can be determined that it is appropriate to roll in the opposite direction, that is, backward. In this case, the gear disk 43 is restricted by the direction restricting block 41 and cannot be rotated. Accordingly, the inner end of the energy storage spring 31 is stationary, while its outer end rotates with the rolling of the disk body 11, and at this time, the energy storage spring 31 starts to store energy. Furthermore, when it cannot roll back, it has shown that the energy storage with respect to the energy storage spring 31 is enough. In this case, if the forcible rolling backward is continued, the circular ring 51 is deformed by receiving an excessively large torsional force, so that the convex teeth 511 are detached from the inner gear ring 52 of the mounting disk 42. To do. Accordingly, the mounting disk 42 and the gear disk 43 rotate with the rolling of the disk body, thereby effectively protecting the energy storage spring 31 from being damaged by excessive energy storage. After the energy is sufficiently stored, when the yo-yo is picked up from the contact surface by the finger of the other hand wound with the string, the frictional resistance of the friction ring 7 is released, and the energy storage spring 31 is restored in the opposite direction. Then, the energy is released, and thereby the disk body 11 is driven to rotate in the opposite direction. Similarly, when the gear disk 43 rotates in the opposite direction, it is not restricted by the direction restricting block 41, so that the gear disk 43 and the disk body 11 rotate synchronously, and the yo-yo ball is released from the hand in this state. , Can fall along the string and eventually rotate at high speed at the end of the string, resulting in a variety of further acrobatics.

Although the present invention has been described with reference to exemplary embodiments, this description is not meant to limit the invention. One skilled in the art can anticipate other variations of the disclosed embodiments by referring to the description of the invention. However, these modifications are encompassed within the scope limited by the claims.

Claims (10)

  A yoyo ball having a frictional kinetic energy storage and acceleration function comprising two rotating bodies (1) and a connecting shaft (2) connecting the two rotating bodies (1), both of the rotating bodies (1) , A disc body (11) and a side cover (12), and the disc body (11) is rotatable with respect to the side cover (12). The friction kinetic energy storage mechanism (3) is provided therein, one end of the friction kinetic energy storage mechanism (3) is connected to the disk body (11), and the other end is the side cover. (12), and by picking the side cover (12) of the two rotating bodies (1), the disk body (11) is brought into contact with the external contact surface, and by friction rolling, The friction kinetic energy storage mechanism (3) stores energy, and after the energy storage, the frictional kinetic energy storage mechanism (3) removes the energy by removing the disk body (11) from contact with the external contact surface. The yo-yo having a frictional kinetic energy storage and acceleration function, wherein the two disk bodies (11) are released and driven to rotate synchronously in a direction opposite to the rolling direction. ball.   Each of the disk bodies (11) is provided with a direction limiting mechanism (4) therein, and the direction limiting mechanism (4) is configured such that the side cover (12) has the friction kinetic energy storage mechanism (3). The direction limiting mechanism (4) has one end connected to the side cover (12) and the other end connected to the friction kinetic energy storage mechanism (3). The rotation direction restricted by the direction restriction mechanism (4) is the same as the energy storage direction of the frictional kinetic energy storage mechanism (3), and the side covers of the two rotating bodies (1) By picking (12), the disc body (11) is brought into contact with an external contact surface, and the friction kinetic energy is generated by friction rolling in the rotational direction restricted by the direction restriction mechanism (4). Characterized in that it adapted to store energy in the built mechanism (3), yo ball having a friction kinetic energy storage and accelerated, as in claim 1.   Each of the disk bodies (11) is provided with an overload protection mechanism (5) therein, and the overload protection mechanism (5) is configured such that the side cover (12) has the friction kinetic energy storage mechanism ( 3), one end of the overload protection mechanism (5) is connected to the side cover (12), and the other end is the friction kinetic energy storage mechanism (3). When the overload energy storage for the frictional motion protection mechanism (3) is performed by pinching the side cover (12), the side cover (12) is activated by the action of the overload protection mechanism. Is detached from the frictional kinetic energy storage mechanism (3), whereby the energy storage for the frictional kinetic energy storage mechanism (3) is stopped. To, yo ball with friction kinetic energy storage and accelerated, as in claim 1.   Each of the disk bodies (11) is provided with a direction restriction mechanism (4) and an overload protection mechanism (5) inside, and the direction restriction mechanism (4) and the overload protection mechanism (5) The side cover (12) is disposed at a position connected to the friction kinetic energy storage mechanism (3), and one end of the direction limiting mechanism (4) is connected to the friction kinetic energy storage mechanism (3). The other end is connected to one end of the overload protection mechanism (5), and the other end of the overload protection mechanism (5) is connected to the side cover (12). The rotation direction restricted by the direction restriction mechanism (4) is the same as the energy storage direction of the frictional kinetic energy storage mechanism (3), and the side cover (12) of the two rotating bodies (1) By picking before The disc body (11) is brought into contact with the external contact surface, and the friction kinetic energy storage mechanism (3) stores energy by friction rolling toward the rotation direction restricted by the direction restriction mechanism (4), and the friction When overload energy storage is performed on the kinetic energy storage mechanism (3), the side cover (12) is detached from the direction limiting mechanism (4) by the action of the overload protection mechanism (5), thereby The yo-yo ball having a friction kinetic energy storage and acceleration function according to claim 1, characterized in that energy storage for the friction kinetic energy storage mechanism (3) is stopped.   The direction restriction mechanism (4) includes a plurality of direction restriction blocks (41), a mounting disk (42) to which all of the direction restriction blocks (41) are attached, and an inner helical gear tooth (431) having a concave shape. A gear disk (43) provided, and the direction restricting block (41) is connected to a bottom surface of the mounting disk (42) by a pin bolt (40) so as to be automatically rotated. And projecting above the mounting disk (42), and the gear disk (43) is placed on the direction restriction block (41), whereby the direction restriction block (41) A limiting pawl clamps the inner spiral gear teeth (431) in one direction to limit the gear disc (43) to rotate in one direction. One end of the frictional kinetic energy storage mechanism (3) is connected to the gear disk (43), and the overload protection mechanism (5) is connected to the mounting disk (42). The yo-yo ball having a friction kinetic energy storage and acceleration function according to claim 4.   The overload protection mechanism (5) includes a circular ring (51), convex teeth (511) are provided in a convex shape on the arc surface of the circular ring (51), and an inner gear ring (52). ) Is engaged with the convex teeth (511), and the inner gear ring (52) is disposed on the upper surface of the mounting disk (42) and is long in the center of the circular ring (51). A convex key (512) is provided, and correspondingly, a long key groove (121) is provided in the side cover (12) to be connected to the long convex key (512). When the overload energy storage for the friction kinetic energy storage mechanism (3) is performed, the circular ring (51) is deformed under stress, and the convex teeth (511) are deformed by the inner gear ring (52). Leaving the direction The limiting mechanism (4) and the friction kinetic energy storage mechanism (3) rotate together with the disk body (11), and the friction kinetic energy storage mechanism (3) stops energy storage. A yoyo ball having a frictional kinetic energy storage and acceleration function according to claim 5.   The friction kinetic energy storage mechanism (3) includes an energy storage spring (31) and a spring case (32), and the energy storage spring (31) is disposed in the spring case (32), and the energy The outer end of the storage spring (31) is clamped and connected to the spring case (32), and the inner end of the energy storage spring (31) is clamped and connected to the direction limiting mechanism (4). The energy storage rotation direction of the energy storage spring (31) is the same as the rotation direction limited by the direction limiting mechanism (4), and the spring case (32) is the disk body (11). The frictional kinetic energy storage and acceleration function according to claim 2, 4, 5, or 6, characterized in that Yo-yo ball that.   A through hole (320) is formed at the center of the spring case (32), and correspondingly, an ear portion (430) is provided in a lower portion of the gear disc (43), and the ear portion (430) enters the spring case (32) through the through hole (320), and a plurality of arcs distributed apart from each other along the periphery of the ear (430). A piece (432) is provided, a gap is maintained between the arc piece (432) and the ear portion (430), and a hook (433) is provided at the lower end of the arc piece (432). After the ear portion (430) of the gear disk is inserted into the through hole (320) of the spring case (32), the hook (433) is extended out of the through hole (320). Fixed to the side of the through hole, Thus, the gear disk (43) is connected to the spring case (32), and the inner end of the energy storage spring (31) is connected to the arc piece (432) of the gear disk (43). The yo-yo ball having a friction kinetic energy storage and acceleration function according to claim 7, wherein the ball is clamped and connected.   A bearing stand (434) is provided at the center of the gear disk (43), and a bearing (6) is mounted thereon, and the connecting shaft (2) is inserted into a central hole of the bearing (6). The yo-yo ball having a friction kinetic energy storage and acceleration function according to claim 8, wherein the yo-yo ball has a friction kinetic energy storage and acceleration function. The disc edge of the disc body (11) is connected to a friction ring (7), and the friction ring (7) is locked and connected to the disc body (11) by a screw. The diameter of the friction ring (7) is larger than the diameter of the disk opening of the disk body (11), and the side cover (12) is placed on the outer surface of the friction ring (7), The yo-yo ball having frictional kinetic energy storage and acceleration functions according to claim 1, characterized in that it is connected to the connection shaft (2) by means of bolts.

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