CN111867697B - Bouncing device and bouncing rotary toy - Google Patents

Abstract

A bouncing device (01) and a bouncing rotary toy comprise a base (001), a bouncing piece (002), a first driving piece (003), a first rotating shaft (004), a flexible winding piece (005) and an elastic piece (006), wherein the first driving piece (003) is installed on the base (001), the first driving piece (003) is connected with the first rotating shaft (004), the first driving piece (003) is configured to drive the first rotating shaft (004) to rotate, one end of the flexible winding piece (005) is fixed on the first rotating shaft (004), and the other end of the flexible winding piece (005) is fixed on the bouncing piece (002); the base (001) and the bouncing piece (002) are connected through the elastic piece (006), and the elastic piece (006) enables the bouncing piece (002) to have a movement trend away from the base (001). The bouncing rotary toy comprises the bouncing device (01). The head of the toy has high bouncing speed and more vivid effect; simple and reasonable structure, small abrasion, long service life and low cost.

Description

Bouncing device and bouncing rotary toy

Technical Field

The disclosure relates to the field of toys, in particular to a bouncing device and a bouncing rotary toy.

Background

At present, the head of a bouncing and rotating toy in the market has two functions of bouncing and rotating. The toy comprises a first motor for realizing bouncing and a second motor for realizing rotation, wherein the first motor is matched with a gear rack structure to realize the rising and falling of the head of the toy, namely, the bouncing function is realized; the second motor rotates to drive the toy head to rotate, and the rotating function is achieved.

The inventor finds in research that the traditional bouncing rotating toy has at least the following disadvantages:

when the toy is used, the bouncing action of the head of the toy is slow in response and poor in experience, and the reciprocating lifting action easily causes abrasion of a gear rack structure, so that the toy is easy to damage and high in cost.

Disclosure of Invention

The object of the present disclosure includes, for example, providing a bouncing device, which improves the deficiencies of the prior art, and which can achieve a rapid bouncing of the toy head, with high experience, less wear and long service life.

Another object of the present disclosure includes, for example, providing a bouncing rotation toy comprising the above-mentioned bouncing device, which has the full functionality of the bouncing device.

The embodiment of the disclosure is realized by the following steps:

the embodiment of the disclosure provides a bouncing device, which comprises a base, a bouncing piece, a first driving piece, a first rotating shaft, a flexible winding piece and an elastic piece, wherein the first driving piece is installed on the base; the base is connected with the bouncing piece through the elastic piece, and the elastic piece enables the bouncing piece to have the tendency of moving away from the base.

Optionally, the base includes a guide rod, the bouncing member has a sliding hole, the guide rod is inserted into the sliding hole, and the guide rod and the bouncing member are in sliding fit along the central axis of the sliding hole.

Optionally, an installation channel is arranged on the guide rod, the installation channel penetrates through two ends of the guide rod along the length direction of the guide rod, and the flexible winding piece is arranged in the installation channel in a penetrating mode.

Optionally, the base further includes a bottom case, the guide rod is installed on the bottom case, the first driving member is installed in the bottom case, and the flexible winding member passes through the bottom case and then is connected to the bouncing member.

Optionally, the bottom shell includes a housing having a mounting groove, and a cover plate mounted on the housing, the cover plate covers a notch of the mounting groove, and the cover plate and the housing together define a receiving chamber for receiving the first driving member.

Optionally, a limiting protrusion portion is disposed on an inner circumferential wall of the sliding hole surrounded by the bouncing member, the limiting protrusion portion protrudes inward from the inner circumferential wall along a radial direction of the sliding hole, the elastic member is located in the sliding hole, one end of the elastic member abuts against an end portion of the guide rod inserted into the sliding hole, and the other end of the elastic member abuts against the limiting protrusion portion.

Optionally, the bouncing piece comprises a first half shell and a second half shell, the first half shell is connected with the second half shell in a buckling mode, and the first half shell and the second half shell jointly define the sliding hole.

Optionally, the bouncing device further comprises a locking mechanism having a braking state and a releasing state, and the locking mechanism is mounted on the base; the braking state means that the locking mechanism allows the first rotating shaft to rotate along a first rotating direction so that the flexible winding piece is wound on the first rotating shaft, and simultaneously limits the first rotating shaft to rotate along a second rotating direction; the releasing state refers to that the locking mechanism releases the brake on the first rotating shaft, so that the flexible winding piece pulls the first rotating shaft to rotate along the second rotating direction under the action of the elastic force of the elastic piece;

wherein the first rotational direction is opposite the second rotational direction.

Optionally, the locking mechanism includes a main gear, a clamping gear and a swinging assembly; the main gear is mounted on the first rotating shaft, the clamping gear is mounted on the swinging assembly, the main gear is meshed with the clamping gear, and the first driving piece is connected to the swinging assembly; the swing assembly is provided with a first working position and a second working position, and when the swing assembly is located at the first working position, the first driving piece transmits torque to the clamping gear through the swing assembly so as to drive the main gear to rotate along the first rotating direction; when the swing assembly is located at the second working position, the clamping gear is separated from the main gear, so that the flexible winding piece pulls the first rotating shaft to rotate along the second rotating direction under the action of the elastic force of the elastic piece.

Optionally, the locking mechanism further comprises a first torsion spring and a power input gear, the swing assembly comprises a swing seat, a swing shaft, a transmission gear, a claw and a second torsion spring, the swing shaft is mounted on the base, the first torsion spring is sleeved outside the swing shaft, the swing seat is mounted on the base through the first torsion spring, and the first torsion spring enables the swing seat to have a movement tendency to rotate relative to the main gear to keep the swing assembly at the first working position; the transmission gear is mounted on the swinging seat, a rotating shaft of the transmission gear is coaxial with the swinging shaft, the transmission gear is meshed with the clamping gear, the clamping jaw is mounted on the swinging seat through the second torsion spring, the second torsion spring enables the clamping jaw to have a movement trend towards the clamping gear to enable the clamping jaw to be clamped on the clamping gear, and the clamping jaw is configured to limit the clamping gear to rotate along the first rotating direction and simultaneously allow the clamping gear to rotate along the second rotating direction; the power input gear is mounted on the base and meshed with the transmission gear, the first driving piece is connected to the power input gear to drive the power input gear to rotate, and when the power input gear rotates along the first rotating direction, the transmission gear rotates along the second rotating direction and drives the swinging seat to swing away from the main gear, so that the locking mechanism is in the releasing state; when the power input gear rotates along the second rotating direction, the power input gear transmits torque to the main gear sequentially through the transmission gear and the clamping gear, and the locking mechanism is enabled to be in the braking state.

Optionally, the swing seat includes a first mounting plate, a second mounting plate, a first mounting shaft, a second mounting shaft, and a third mounting shaft, the first mounting plate and the second mounting plate are disposed opposite to each other, two ends of the first mounting shaft are mounted on the first mounting plate and the second mounting plate, two ends of the second mounting shaft are mounted on the first mounting plate and the second mounting plate, two ends of the third mounting shaft are mounted on the first mounting plate and the second mounting plate, the clamping gear is mounted on the first mounting shaft, the transmission gear is mounted on the second mounting shaft, and the clamping jaw is mounted on the third mounting shaft; the swing shaft is mounted on the first mounting plate.

Optionally, the base is provided with a limiting portion, the swinging seat abuts against the limiting portion under the action of the first torsion spring, and the limiting portion is configured to limit the swinging seat to swing in a direction close to the main gear.

Optionally, the bouncing device further comprises a belt transmission mechanism and a gear transmission mechanism, the belt transmission mechanism comprises a driving pulley, a driven pulley and a transmission belt, the driving pulley is mounted on the first driving piece, the driven pulley is mounted on the base, and the transmission belt is wound outside the driving pulley and the driven pulley; the output end gear of the gear transmission mechanism is coaxially arranged with the driven belt wheel, and the input end gear of the gear transmission mechanism is meshed with the power input gear.

Optionally, the bouncing device further comprises an installation box, the locking mechanism is installed in the installation box, the first driving piece is installed on the installation box, and the installation box is installed on the base.

Optionally, the bouncing device further comprises a bobbin, the bobbin is sleeved outside the first rotating shaft, the bobbin is in circumferential limiting connection with the first rotating shaft, and one end of the flexible winding piece is fixed on the bobbin.

Embodiments of the present disclosure also provide a bouncing swivel toy, which includes the aforementioned bouncing device, including a toy head, a second driving element, and the aforementioned bouncing device, wherein the second driving element is mounted on the bouncing element, and the second driving element is provided with a second rotation axis configured to mount the toy head.

Optionally, rotatory toy of spring still includes the mounting disc, be provided with the mounting hole on the mounting disc and with the installation breach of mounting hole intercommunication, it bears arch and joint arch to be provided with on the spring piece, bear the arch with the joint arch is all followed the radial protrusion of spring piece the outer peripheral face of spring piece, bear the arch with the joint arch is followed the spring direction interval of spring piece is arranged, the mounting disc joint is in bear the arch with between the joint arch.

Optionally, a limiting protruding structure and a shifting piece are arranged on the mounting disc, the shifting piece is mounted on the mounting disc, and the clamping protruding joint is arranged between the limiting protruding structure and the shifting piece.

Optionally, the bouncing rotary toy further comprises a gear box, the second driving piece is connected with the second rotating shaft through the gear box, and the gear box is installed on the bouncing piece.

Optionally, the bouncing and rotating toy further comprises a mounting head, the mounting head is mounted on the second rotating shaft, and the toy head is detachably connected to the mounting head.

Compared with the prior art, the beneficial effects of the embodiment of the present disclosure include, for example:

in summary, in the bouncing device of the present embodiment, the flexible winding element is wound around the first rotating shaft by the first driving element, and the elastic element is in a compressed state and has an elastic force of restoring deformation, so that the bouncing element tends to move away from the base. When the bouncing device is needed to be used, the pulling force of the flexible winding piece on the bouncing piece is relieved, namely the straightening state of the flexible winding piece is relieved, and at the moment, under the action of the elastic force of the elastic piece, the bouncing piece pops relative to the base along the direction far away from the base, so that bouncing is realized. The bounce piece reacts quickly when bouncing, and the experience degree is high. And the traditional gear rack structure is replaced by the matching structure of the flexible winding piece and the elastic piece, so that the structure is simpler, and the manufacturing cost is reduced. And the abrasion is small in the bouncing process, the service life is long, and the use cost is reduced.

Drawings

To more clearly illustrate the technical solutions of the embodiments of the present disclosure, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present disclosure and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings may be obtained from the drawings without inventive effort.

Fig. 1 is a schematic view of a bouncing apparatus provided by an embodiment of the present disclosure;

fig. 2 is a schematic view of a bottom case provided in an embodiment of the present disclosure;

FIG. 3 is a schematic cross-sectional view of a bouncing member provided by an embodiment of the disclosure;

FIG. 4 is a schematic view of the mounting box, the first driving member, and the belt transmission provided in the embodiments of the present disclosure;

FIG. 5 is an exploded view of a portion of a bouncing device according to an embodiment of the disclosure;

FIG. 6 is a schematic diagram of a locking mechanism and a gear assembly provided in an embodiment of the present disclosure;

fig. 7 is a schematic diagram illustrating a position of a swing assembly and a main gear according to an embodiment of the disclosure;

FIG. 8 is a schematic view of a swing assembly provided by an embodiment of the present disclosure;

FIG. 9 is a schematic illustration of the housing and mounting box mating provided by an embodiment of the present disclosure;

FIG. 10 is a schematic view of a second half-enclosure provided by embodiments of the present disclosure;

FIG. 11 is a schematic view of a bouncing rotation toy provided by an embodiment of the present disclosure;

FIG. 12 is a schematic view of a mounting plate provided by an embodiment of the present disclosure;

fig. 13 is a schematic view illustrating a mounting plate mounted on a bouncing member according to an embodiment of the disclosure;

FIG. 14 is a schematic view of a gearbox provided by an embodiment of the present disclosure;

fig. 15 is a schematic view of a gearbox and a mounting head provided in an embodiment of the disclosure.

Icon: 01-a bouncing device; 001-base; 100-a bottom shell; 101-a housing; 1010-a necking end; 1011-open end; 1012-mounting grooves; 1013-a threaded hole; 1014-a card board; 1015-clamping groove; 1016-bayonet; 1017-threading hole; 1018 — sound propagation hole; 102-a cover plate; 110-a guide bar; 111-mounting a channel; 120-a containment chamber; 002-bouncing element; 200-a first half-shell; 210-a second half-shell; 220-limit boss; 221-semi-cylindrical protrusion; 230-a bearing projection; 240-clamping protrusions; 250-a clamping area; 003-a first driving member; 004-first rotating shaft; 005-flexible wrapping; 006-elastic member; 007-an installation box; 700-a first half-shell; 701-penetrating a shaft hole; 710-a second half-enclosure; 711-mounting a through hole; 720-cylindrical shell; 721-strip threading mouth; 730-a limiting plate; 731-limiting groove; 7310-a first stopper; 7311-a second stopper; 008-a locking mechanism; 800-main gear; 810-snap-fit gear; 820-a first torsion spring; 830-a power input gear; 840-a swing assembly; 841-first working position; 842-a second working position; 843-a swing seat; 8430-a first mounting plate; 8431-a second mounting plate; 8432-a first positioning shaft; 8433-a second positioning shaft; 8434-a third positioning shaft; 844-oscillating shaft; 845-drive gear; 846-jaws; 847-a second torsion spring; 850-first installation axis; 009-gear drive; 900-output end gear; 910-intermediate gear; 920-input gear; 930 — second mounting shaft; 940-third installation axis; 950-a fourth installation shaft; 010-belt drive; 011-driving pulley; 012-a driven pulley; 013-a drive belt; 020-bobbin; 030-sealing plate; 02-toy head; 03-a second drive member; 04-a second rotating shaft; 05-mounting a disc; 051-mounting holes; 052-installing a gap; 053-limiting convex structure; 054-a toggle piece; 06-a gear box; 061-case; 062-a gear assembly; 0621-a first gear; 0622-a second gear; 0623-third gear; 0624-fourth gear; 0625-fifth gear; 0626-sixth gear; 0627-first axis; 0628-the second axis; 0629-third axis; 0601-fourth axis; 0602-fifth axis; 07-a belt drive assembly; 071-a first pulley; 072-second pulley; 073-belt body; 08-mounting head.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present disclosure more clear, the technical solutions of the embodiments of the present disclosure will be described clearly and completely with reference to the drawings in the embodiments of the present disclosure, and it is obvious that the described embodiments are some, but not all embodiments of the present disclosure. The components of the embodiments of the present disclosure, generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present disclosure, presented in the figures, is not intended to limit the scope of the claimed disclosure, but is merely representative of selected embodiments of the disclosure. All other embodiments, which can be derived by a person skilled in the art from the embodiments disclosed herein without making any creative effort, shall fall within the protection scope of the present disclosure.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present disclosure, it should be noted that if the terms "center", "inside", "outside", etc. are used for indicating the orientation or positional relationship based on the orientation or positional relationship shown in the drawings or the orientation or positional relationship which the present invention is used to usually place, the description is only for convenience of describing and simplifying the present disclosure, but not for indicating or implying that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present disclosure.

Furthermore, the appearances of the terms "first," "second," "third," and the like, if any, are only used to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

Furthermore, the terms "horizontal", "vertical", "overhang" and the like do not require that the components be absolutely horizontal or overhang, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present disclosure, it should be further noted that unless otherwise explicitly stated or limited, the terms "disposed," "mounted," "connected," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present disclosure can be understood in specific instances by those of ordinary skill in the art.

It should be noted that the features in the embodiments of the present disclosure may be combined with each other without conflict.

In the embodiments of the present disclosure, unless otherwise specified, "first rotation direction" refers to a direction indicated by an ab arrow in the drawings, "second rotation direction" refers to a direction indicated by a cd arrow in the drawings, "first rotation direction" and "second rotation direction" are opposite; the "bounce direction" and the "direction away from the base" are both directions indicated by the ef arrow.

Examples

This embodiment provides a bouncing device 01, is applicable to on the toy, makes the toy possess the spring function, and the toy reacts rapidly when realizing the spring function, and experience degree is high.

Referring to fig. 1, the bouncing device 01 of the present embodiment includes a base 001, a bouncing element 002, a first driving element 003, a first rotating shaft 004, a flexible winding element 005, and an elastic element 006, wherein the first driving element 003 is mounted on the base 001, the first driving element 003 is connected to the first rotating shaft 004, the first driving element 003 is configured to drive the first rotating shaft 004 to rotate, one end of the flexible winding element 005 is fixed on the first rotating shaft 004, and the other end of the flexible winding element 005 is fixed on the bouncing element 002; the base 001 and the bouncing element 002 are connected through the elastic element 006, and the elastic element 006 makes the bouncing element 002 move away from the base 001.

In the case of the bouncing device 01 according to the present embodiment, the flexible winding member 005 is not wound around the first rotation axis 004 in the initial state, that is, the bouncing member 002 is in the state after the bouncing operation is completed, and when the bouncing device 01 is required to perform the bouncing operation, the bouncing device 01 in the initial state needs to be changed to the energy collecting state. The working process that bouncer 01 is converted from the initial state to the energy-gathering state is, operate first driving piece 003, make first driving piece 003 drive first axis of rotation 004 and rotate along the direction that the ab arrow points to, first axis of rotation 004 pulling flexible winding piece 005 makes flexible winding piece 005 around establishing on first axis of rotation 004, flexible winding piece 005 is around establishing the in-process and driving bounce piece 002 and slide along the direction that the fe arrow points to (the direction that is close to base 001), this in-process elastic component 006 is compressed gradually, elastic component 006 reserves the elasticity that has the resilience deformation, so that bounce piece 002 has the trend of moving along the direction that the ef arrow points to. The first driving member 003 drives the first rotating shaft 004 to rotate until the flexible winding member 005 is completely wound around the first rotating shaft 004, and then the rotation of the first rotating shaft 004 is stopped, and this state can be regarded as an energy collecting state. In the energy-gathered state, since the flexible winding member 005 pulls the bouncing member 002, the elastic force of the elastic member 006 is balanced by the flexible winding member 005, and the bouncing member 002 cannot be sprung out relative to the base 001 in the direction indicated by the ef arrow. When the bouncing function of the bouncing device 01 needs to be realized, the pulling force of the flexible winding piece 005 on the bouncing piece 002 is released, namely, the straightening state of the flexible winding piece 005 is released, at this time, under the action of the elastic force of the elastic piece 006, the bouncing piece 002 is bounced relative to the base 001 along the direction indicated by the ef arrow, and the bouncing function is realized. The external force of spring 002 spring is provided by elastic component 006, and elastic component 006's elasticity has the transient nature, can make spring 002 spring action reaction rapidly, and experience degree is high, can understand that spring 002 directly launches out along the direction that the ef arrow points to. The conventional rack and pinion structure is replaced by the matching structure of the flexible winding member 005 and the elastic member 006, the structure is simpler, and the manufacturing cost is reduced. And the abrasion of the elastic member 006, the first rotating shaft 004 and the flexible winding member 005 is small in the bouncing process, the service life is long, and the use cost is reduced.

It should be noted that the energy-gathered state of the bouncing device 01 can be determined not only by completely winding the flexible winding member 005 on the first rotating shaft 004, but also by compressing the elastic member 006 fully, or compressing the elastic member 006 only for a certain distance, in other words, the energy-gathered state of the bouncing device 01 can be determined by only satisfying the elastic force of the elastic member 006 with a certain amount of restoring deformation.

It should be noted that the elastic member 006 may be a spring, a leaf spring or a rubber pad, which is not listed here.

It should be noted that the flexible wrapping 005 can be, but is not limited to, a rope.

Referring to fig. 2, in the present embodiment, the base 001 optionally includes a bottom case 100 and a guide bar 110. The bottom case 100 includes a housing 101 and a cover plate 102, the housing 101 is a circular truncated cone-shaped structure having a mounting groove 1012, a reduced end 1010 of the housing 101 is closed, that is, the reduced end 1010 is an end where a groove bottom of the mounting groove 1012 is located, and an open end 1011 of the housing 101 is an end where a notch of the mounting groove 1012 is located. The peripheral wall of the housing 101 near the open end 1011 is provided with at least two threaded holes 1013, and the at least two threaded holes 1013 are uniformly spaced along the circumferential direction of the housing 101. Two opposite clamping plates 1014 are arranged on the inner wall of the reducing end 1010 of the shell 101, the clamping plates 1014 are perpendicular to the reducing end 1010, bending parts are arranged on the clamping plates 1014 along the two radial sides of the reducing end 1010, a clamping groove 1015 is defined between the two bending parts of each clamping plate 1014, and a bayonet 1016 is defined between the two clamping plates 1014. The throat end 1010 of casing 101 is provided with the through wires hole 1017 with mounting groove 1012 intercommunication, and through wires hole 1017 is cylindrical hole, and the centre of a circle of through wires hole 1017 is located the middle part position of the throat end 1010 of casing 101. The cover plate 102 is a circular plate, at least two through holes for screws to pass through are formed in the cover plate 102, the at least two through holes are arranged at intervals along the circumferential direction of the cover plate 102, the cover plate 102 covers the open end 1011 of the housing 101, the cover plate 102 and the housing 101 together define the accommodating chamber 120, and the screws pass through the through holes and are screwed in the corresponding threaded holes 1013, so that the cover plate 102 and the housing 101 are detachably connected. The guide bar 110 is a hollow bar, the guide bar 110 has an installation channel 111, both ends of the installation channel 111 penetrate both ends of the guide bar 110 along a length direction of the guide bar 110, and a cross-sectional profile of the guide bar 110 perpendicular to a central axis direction thereof is a circular ring shape. The guide rod 110 is installed at the end of the housing 101 where the necking end 1010 is located, the central axis of the guide rod 110 is collinear with the central axis of the threading hole 1017, and the installation channel 111 is communicated with the threading hole 1017.

In other embodiments, the guide bar 110 is integrally formed with the housing 101.

Optionally, a sound propagation hole 1018 is provided in the housing 101. Can install loudspeaker in casing 101, can play the audio frequency, the audio frequency spreads the hole 1018 from the sound and spreads, and the function is abundanter, and experience is higher.

Referring to fig. 1 and fig. 3, in the present embodiment, optionally, the bouncing element 002 is a hollow rod, the bouncing element 002 is sleeved outside the guide rod 110, and the bouncing element 002 slides back and forth relative to the guide rod 110 along the central axis direction of the guide rod 110. The bouncing element 002 comprises a semi-cylindrical first half shell 200 and a semi-cylindrical second half shell 210, and the first half shell 200 and the second half shell 210 are buckled to form the cylindrical bouncing element 002. A limiting convex part 220 is arranged on the inner peripheral wall of the first half shell 200 or/and the second half shell 210, the limiting convex part 220 is arranged near the end part of the bouncing piece 002 far away from the guide rod 110, and the protruding direction of the limiting convex part 220 is inward along the radial direction of the bouncing piece 002. Optionally, the limiting protrusion 220 includes a semi-cylindrical protrusion 221 disposed on an inner wall of the first half-shell 200 and a semi-cylindrical protrusion 221 disposed on an inner wall of the second half-shell 210, and after the first half-shell 200 and the second half-shell 210 are fastened, the two semi-cylindrical protrusions 221 cooperate to form a cylindrical protrusion.

Referring to fig. 1 and 3, optionally, the ends of the first half shell 200 and the second half shell 210 away from the guide bar 110 are provided with a bearing protrusion 230 and a clamping protrusion 240, and the number of the bearing protrusions 230 and the number of the clamping protrusions 240 are set as required. In this embodiment, the first half shell 200 is provided with two bearing protrusions 230 and two clamping protrusions 240, the two bearing protrusions 230 are located on two edges of the first half shell 200 in the circumferential direction, the two clamping protrusions 240 are located on two edges of the first half shell 200 in the circumferential direction, and the bearing protrusions 230 and the clamping protrusions 240 are arranged at intervals along the direction indicated by ef. Correspondingly, the second half-shell 210 is provided with two bearing protrusions 230 and two clamping protrusions 240, the two bearing protrusions 230 are located on two edges of the second half-shell 210 in the circumferential direction, the two clamping protrusions 240 are located on two edges of the second half-shell 210 in the circumferential direction, and the bearing protrusions 230 and the clamping protrusions 240 are arranged at intervals along the direction indicated by ef. A clamping area 250 is formed between the carrier protrusion 230 and the clamping protrusion 240.

Optionally, a through hole for fixing the flexible winding member 005 is provided on the bearing protrusion 230 or the catching protrusion 240.

Referring to fig. 4-6, in the present embodiment, optionally, the bouncing device 01 further includes a mounting box 007, a locking mechanism 008, a gear transmission mechanism 009, a belt transmission mechanism 010, and a bobbin 020, wherein the locking mechanism 008, the gear transmission mechanism 009, and the belt transmission mechanism 010 are all mounted on the mounting box 007, the mounting box 007 is mounted in the accommodating chamber 120, and the bobbin 020 is mounted on the first rotating shaft 004.

Referring to fig. 5, the mounting box 007 may alternatively include a first half-box 700, a second half-box 710 and a cylindrical shell 720, wherein the first half-box 700 and the second half-box 710 are fastened to form the rectangular parallelepiped-shaped mounting box 007. The first half-case 700 and the second half-case 710 are connected by screws. The cylinder shell 720 is installed on the first half-shell 700, two ends of the cylinder shell 720 are open, the first half-shell 700 is provided with a shaft penetrating hole 701 communicated with the cylinder shell 720, the shaft penetrating hole 701 is a cylindrical hole, the shaft penetrating hole 701 and the cylinder shell 720 are coaxially arranged, a strip-shaped threading opening 721 is arranged on the circumferential wall of the cylinder shell 720, and the length direction of the strip-shaped threading opening 721 is parallel to the central axis direction of the cylinder shell 720 and extends. The second half-case shell 710 is provided with an installation through hole 711 for the first rotating shaft 004 to penetrate through, after the first half-case shell 700 and the second half-case shell 710 are buckled, the installation through hole 711 and the shaft penetrating hole 701 are coaxially arranged, one end of the first rotating shaft 004 is inserted into the installation through hole 711, and the other end of the first rotating shaft 004 extends out of the shaft penetrating hole 701. Referring to fig. 10, a limiting plate 730 is disposed in the second half-case 710, the limiting plate 730 is perpendicular to the bottom plate of the second half-case 710, a limiting groove 731 is disposed on the limiting plate 730, a first limiting portion 7310 is disposed on a side wall of the limiting groove 731 close to the mounting through hole 711, and a second limiting portion 7311 is disposed on a side wall of the limiting groove 731 away from the mounting through hole 711. Referring to fig. 9, the first half-case 700 and the second half-case 710 are clamped in the clamping groove 1015 defined by the two clamping plates 1014, that is, the installation case 007 is clamped and matched with the bottom case 100, and after the installation is completed, the strip-shaped threading opening 721 is communicated with the threading hole 1017 on the reducing end 1010 of the casing 101.

Referring to fig. 5-6, the locking mechanism 008 may optionally include a main gear 800, a latch gear 810, a first torsion spring 820, a power input gear 830, and a swing assembly 840. The main gear 800 is mounted on the first rotating shaft 004, the latch gear 810 is mounted on the swing assembly 840, the main gear 800 is engaged with the latch gear 810, and the first driving member 003 is connected to the swing assembly 840. Referring to fig. 7, the swing assembly 840 has a first working position 841 and a second working position 842, when the swing assembly 840 is located at the first working position 841, the first driving member 003 transmits torque to the latch gear 810 through the swing assembly 840 to drive the main gear 800 to rotate along the direction indicated by the arrow ab, the main gear 800 rotates to drive the first rotating shaft 004 to rotate, the flexible winding member 005 is wound on the first rotating shaft 004, and the bouncing apparatus 01 is in an energy-gathering state; when the swing assembly 840 is located at the second working position 842, the latch gear 810 is disengaged from the main gear 800, the latch gear 810 is not engaged with the main gear 800, and if the bouncing device 01 is in the energy-gathering state, that is, the elastic member 006 stores a certain amount of elastic force, the flexible winding member 005 is pulled under the elastic force of the elastic member 006 and drives the first rotating shaft 004 to rotate along the direction indicated by the cd arrow, the bouncing member 002 pops up along the ef direction, and the bouncing device 01 is changed from the energy-gathering state to the initial state, that is, the popping up action of the bouncing device 01 is realized.

Referring to fig. 5 and 6, the swing assembly 840 may optionally include a swing seat 843, a swing shaft 844, a transmission gear 845, a pawl 846, and a second torsion spring 847. A swing shaft 844 is mounted on the first half casing 700, and the swing shaft 844 rotates along its own axis with respect to the first half casing 700. The first torsion spring 820 is sleeved outside the swinging shaft 844, the swinging seat 843 is mounted on the first half-case 700 through the first torsion spring 820, that is, a first power arm of the first torsion spring 820 is clamped on the first half-case 700, a second power arm of the first torsion spring 820 is clamped on the swinging seat 843, and the first torsion spring 820 makes the swinging seat 843 have a movement tendency to rotate relative to the main gear 800 so as to keep the swinging assembly 840 at the first working position 841. In other words, the latch gear 810 can always keep engaged with the main gear 800 under the action of the first torsion spring 820, after the installation is completed, the swing seat 843 is located in the limiting groove 731, one side of the swing seat 843 abuts against the first limiting portion 7310 under the action of the first torsion spring 820, the first limiting portion 7310 is configured to limit the swing seat 843 to swing in a direction close to the main gear 800, on the premise that the latch gear 810 and the main gear 800 are engaged with each other, only partial or no elastic force of the first torsion spring 820 acts on the main gear 800 through the latch gear 810, so that the pressing force between the latch gear 810 and the main gear 800 is reduced, the engagement between the latch gear 810 and the main gear 800 is more reliable, the wear is less, the damage is less, and the service life is long.

The transmission gear 845 is installed on the swinging seat 843, a rotating shaft of the transmission gear 845 and the swinging shaft 844 are coaxially arranged, the transmission gear 845 is meshed with the clamping gear 810, the jaw 846 is installed on the swinging seat 843 through a second torsion spring 847, namely the second torsion spring 847 is sleeved on the rotating shaft of the jaw 846, a first power arm of the second torsion spring 847 is clamped on the jaw 846, a second power arm of the second torsion spring 847 is clamped on the swinging seat 843, the second torsion spring 847 enables the jaw 846 to have a movement trend of rotating towards the clamping gear 810 so that the jaw 846 is clamped on the clamping gear 810, and the jaw 846 is configured to limit the clamping gear 810 to rotate along the direction indicated by an ab arrow and simultaneously allow the clamping gear 810 to rotate along the direction indicated by the arrow ef. In other words, pawl 846 cooperates with ratchet gear 810 to form a drive structure that allows unidirectional rotation of ratchet gear 810 in the direction of the ef arrow.

The power input gear 830 is installed in the installation box 007 through the first installation shaft 850, the power input gear 830 is engaged with the transmission gear 845, and the first driving member 003 is connected to the power input gear 830 through the gear transmission assembly 062 to drive the power input gear 830 to rotate. When the power input gear 830 rotates along the direction indicated by the arrow ab, the transmission gear 845 rotates along the direction indicated by the arrow ef, the transmission gear 845 transmits torque to the clamping gear 810 to drive the clamping gear 810 to rotate along the direction indicated by the arrow ab, however, due to the structural design of the clamping jaw 846, the clamping gear 810 is limited by the clamping jaw 846 to rotate along the direction indicated by the arrow ab, at this time, the swinging seat 843, the clamping gear 810 and the transmission gear 845 are of an integrated structure which moves synchronously, the swinging seat 843, the clamping gear 810 and the transmission gear 845 rotate around the rotation axis of the transmission gear 845 along the direction indicated by the arrow ef, and finally the swinging seat 843 swings away from the main gear 800, so that the locking mechanism 008 is in a release state. That is, the locking mechanism 008 releases the rotation restriction of the first rotating shaft 004 in the direction indicated by the ef arrow, and the flexible winding member 005 pulls the first rotating shaft 004 to rotate in the direction indicated by the ef arrow by the elastic force of the elastic member 006, thereby realizing the pop-up operation of the pop-up member 002.

It should be noted that, in the process of swinging the swinging seat 843 away from the main gear 800, due to the structural design of the second limiting portion 7311, the swinging angle of the swinging seat 843 is limited, and the swinging seat 843 does not swing to the position where it collides with the power input gear 830, which is safe and reliable. Obviously, the swinging angle of the swinging seat 843 away from the main gear 800 can be changed by providing the second limiting portion 7311, and the position of the second limiting portion 7311 is not specifically limited, so as to ensure that the swinging seat 843 swings by a sufficient angle to separate the latch gear 810 on the swinging seat 843 from the main gear 800, that is, after the swinging seat 843 swings, the locking mechanism 008 can be in a release state.

When the power input gear 830 rotates in the direction indicated by the ef arrow, the power input gear 830 transmits the torque to the main gear 800 through the transmission gear 845 and the engaging gear 810 in sequence, the main gear 800 can rotate in the direction indicated by the ab arrow, the flexible winding member 005 is wound on the first rotating shaft 004, meanwhile, the main gear 800 cannot rotate in the direction indicated by the ef arrow, and at this time, the locking mechanism 008 is in a braking state.

Referring to fig. 8, the swing seat 843 may optionally include a first mounting plate 8430 having a triangular plate shape, a second mounting plate 8431 having a triangular plate shape, a first positioning shaft 8432, a second positioning shaft 8433, and a third positioning shaft 8434. The first mounting plate 8430 and the second mounting plate 8431 are arranged oppositely, two ends of a first positioning shaft 8432 are mounted on the first mounting plate 8430 and the second mounting plate 8431, two ends of a second positioning shaft 8433 are mounted on the first mounting plate 8430 and the second mounting plate 8431, two ends of a third positioning shaft 8434 are mounted on the first mounting plate 8430 and the second mounting plate 8431, and the first positioning shaft 8432, the second positioning shaft 8433 and the third positioning shaft 8434 are respectively located at positions, close to three corners, of the first mounting plate 8430 or the second mounting plate 8431. The clamping gear 810 is mounted on the first positioning shaft 8432, the transmission gear 845 is mounted on the second positioning shaft 8433, and the claw 846 is mounted on the third positioning shaft 8434. The swing shaft 844 is mounted on the first mounting plate 8430. In other embodiments, the swing shaft 844 is integrally formed with the first mounting shaft 850.

Referring to fig. 5 and 6, optionally, the gear transmission mechanism 009 includes an output end gear 900, an intermediate gear 910, an input end gear 920, a second mounting shaft 930, a third mounting shaft 940 and a fourth mounting shaft 950, the output end gear 900 is coaxially disposed with the driven pulley 012, the output end gear 900 is sleeved on the second mounting shaft 930, the intermediate gear 910 is sleeved on the third mounting shaft 940, the input end gear 920 is sleeved on the fourth mounting shaft 950, the output end gear 900, the intermediate gear 910 and the input end gear 920 are sequentially engaged, and the input end gear 920 is engaged with the power input gear 830. Both ends of the second mounting shaft 930 are mounted on the first half-cabinet 700 and the second half-cabinet 710, respectively, both ends of the third mounting shaft 940 are mounted on the first half-cabinet 700 and the second half-cabinet 710, respectively, and both ends of the fourth mounting shaft 950 are mounted on the first half-cabinet 700 and the second half-cabinet 710, respectively. Optionally, the intermediate gear 910, the input end gear 920, the power input gear 830 and the transmission gear 845 are dual gears, and the gear transmission mechanism 009 forms a speed reduction mechanism, so that the transmission is more labor-saving. Obviously, the number of gears of the gear train 009 is set as desired and is not listed here.

Referring to fig. 4, the belt transmission mechanism 010 includes a driving pulley 011, a driven pulley 012 and a transmission belt 013, wherein the driving pulley 011 is mounted on the first driving member 003, the driven pulley 012 is mounted on a shaft section of the second mounting shaft 930 extending out of the second half-case 710, and the transmission belt 013 is wound around the driving pulley 011 and the driven pulley 012. First driving piece 003 drive driving pulley 011 rotates, transmits power to driven pulley 012 through driving belt 013, and driven pulley 012 rotates and drives second installation axle 930 and rotate, and then drives output gear 900 and rotates, with power transmission to gear drive mechanism 009.

Referring to fig. 5, optionally, the bobbin 020 is a cylindrical bobbin, the first rotating shaft 004 has a shaft section with a polygonal cross section, such as but not limited to a square, the bobbin 020 has a through hole with a square cross section, the bobbin 020 is inserted into the first rotating shaft 004, the bobbin 020 rotates together with the first rotating shaft 004, the bobbin 020 is located in the cylinder housing 720, and a sealing plate 030 is provided at a port of the cylinder housing 720 far from the first half-case 700 to prevent the bobbin 020 from sliding out of the cylinder housing 720. One end of the flexible winding member 005 is fixed to the bobbin 020. The bobbin 020 increases the circumference of the cross-sectional outer contour of the first rotating shaft 004, and a longer flexible winding piece 005 can be wound around the first rotating shaft 004 in one rotation, so that the time for the bouncing device 01 to change from the initial state to the energy gathering state is shortened.

Alternatively, the first driving member 003 may be a motor or a servo motor.

The bouncing device 01 provided by the embodiment has the advantages that the first driving piece 003 is installed on the second half box shell 710, the output shaft of the first driving piece 003 extends out of the second half box shell 710, the driving pulley 011 is installed on the output shaft, the driven pulley 012 and the output gear 900 share the same rotating shaft, two ends of the rotating shaft are installed on the first half box shell 700 and the second half box shell 710, and the driven pulley 012 is positioned outside the second half box shell 710. The output gear 900, the intermediate gear 910, the input gear 920, the power input gear 830 and the swing assembly 840 are all installed in a cavity surrounded by the first half-case 700 and the second half-case 710. The first rotating shaft 004 is inserted into the shaft penetrating hole 701 and the mounting through hole 711, one end of the first rotating shaft 004 extends into the cylindrical shell 720 from the shaft penetrating hole 701, the main gear 800 is sleeved outside the first rotating shaft 004, and the output end gear 900, the intermediate gear 910, the input end gear 920, the power input gear 830, the transmission gear 845, the clamping gear 810 and the main gear 800 are meshed in sequence. Bobbin 020 is located cylinder shell 720 to the cover is established outside first axis of rotation 004, bobbin 020 and first axis of rotation 004 circumference are spacing to be connected, the one end of flexible winding piece 005 is fixed on bobbin 020, the other end of flexible winding piece 005 stretches out and enters into the installation passageway 111 of guide bar 110 from bar threading mouth 721, the one end that bobbin 020 was kept away from to flexible winding piece 005 is worn out and is fixed on the protruding 230 of bearing or the protruding 240 of joint on the piece 002 from installation passageway 111, the piece 002 slip cover is established outside guide bar 110. The mounting box 007 is clamped between two clamping plates 1014 inside the housing 101.

In other embodiments, the output shaft of the first driving element 003 can be directly connected to the first rotating shaft 004, or the first rotating shaft 004 and the output shaft of the first driving element 003 are integrally formed, and the first driving element 003 directly drives the first rotating shaft 004 to rotate, so that the flexible winding element 005 is wound around the first rotating shaft 004.

Examples

The embodiment provides a bouncing rotating toy, the embodiment is an improvement on the technical scheme described in the embodiment, the technical scheme described in the embodiment is also applicable to the embodiment, and the technical scheme disclosed in the embodiment is not repeatedly described in order to avoid repeated encumbrance.

Referring to fig. 11, the present embodiment provides a bouncing toy, which includes a toy head 02, a second driving member 03, a second rotating shaft 04, a mounting plate 05, a gear box 06, a belt transmission assembly 07, a mounting head 08, and the bouncing apparatus 01 of the above embodiments. The mounting plate 05 is mounted on the bouncing member 002, the gear box 06 is mounted on the mounting plate 05, the second driving member 03 is mounted on the gear box 06, the mounting head 08 and the second rotating shaft 04 are both mounted on the gear box 06, and the toy head 02 is detachably mounted on the mounting head 08.

Please refer to fig. 12 and fig. 13, optionally, a mounting hole 051 and two mounting notches 052 communicated with the mounting hole 051 are provided on the mounting plate 05, the mounting plate 05 is sleeved outside the bouncing piece 002 through the mounting hole 051, in the practical operation, the two mounting notches 052 correspond to the two clamping protrusions 240 on the bouncing piece 002, the two clamping protrusions 240 can penetrate through the mounting notches 052 so that the mounting plate 05 is sleeved outside the bouncing piece 002, after the clamping protrusions 240 penetrate through the mounting notches 052, the mounting plate 05 is rotated, the bearing protrusions 230 and the clamping protrusions 240 are dislocated with the mounting notches 052, and the mounting plate 05 is clamped between the clamping protrusions 240 and the bearing protrusions 230. Optionally, two limiting protrusion structures 053 and a toggle part 054 are arranged on the mounting plate 05, the two limiting protrusion structures 053 are symmetrically arranged with a central plane of the mounting plate 05 passing through the central axis thereof as a symmetry plane, and the two limiting protrusion structures 053 are located on the same diameter of the mounting plate 05. The toggle 054 is fixed to the mounting plate 05 by screws. When installing mounting disc 05 on spring piece 002, arrange mounting disc 05 in the in-process that rotates mounting disc 05 behind the joint region 250, two spacing protruding structure 053 and two protruding 240 structures of joint butt respectively, continue to rotate with restriction mounting disc 05, at this moment, will dial a 054 butt and deviate from the protruding 240 one side of joint at spacing protruding structure 053, spacing protruding structure 053 can not revolve, mounting disc 05 joint is on spring piece 002, the position of mounting disc 05 is firm reliable, can not drop from spring piece 002 automatically, use safe and reliable.

Referring to fig. 14, optionally, the gear box 06 includes a box 061 and a gear assembly 062, the gear assembly 062 including a first gear 0621, a second gear 0622, a third gear 0623, a fourth gear 0624, a fifth gear 0625, a sixth gear 0626, a first shaft 0627, a second shaft 0628, a third shaft 0629, a fourth shaft 0601, and a fifth shaft 0602. The first shaft 0627, the second shaft 0628, the third shaft 0629, the fourth shaft 0601, the fifth shaft 0602 and the second rotating shaft 04 are all installed on the box body 061, the first gear 0621 is sleeved outside the first shaft 0627, the second gear 0622 is sleeved outside the second shaft 0628, the third gear 0623 is sleeved outside the third shaft 0629, the fourth gear 0624 is sleeved outside the fourth shaft 0601, the fifth gear 0625 is sleeved outside the fifth shaft 0602, the sixth gear 0626 is sleeved outside the second rotating shaft 04, and the first gear 0621, the second gear 0622, the third gear 0623, the fourth gear 0624, the fifth gear 0625 and the sixth gear 0626 are meshed in sequence. One end of the first shaft 0627 protrudes out of the case 061, and one end of the second rotating shaft 04 protrudes out of the case 061.

It should be noted that the number of gears of the gear assembly 062 is set as required, and is not listed here. At least one of the first gear 0621, the second gear 0622, the third gear 0623, the fourth gear 0624, the fifth gear 0625, and the sixth gear 0626 may be provided as a duplicate gear, as needed.

Referring to fig. 15, optionally, the belt driving assembly 07 includes a first belt pulley 071, a second belt pulley 072 and a belt body 073, the first belt pulley 071 is mounted on the output shaft of the second driving member 03, the second belt pulley 072 is mounted on the shaft segment of the first shaft 0627 extending out of the box body 061, and the belt body 073 is wound around the first belt pulley 071 and the second belt pulley 072.

Alternatively, the mounting head 08 is mounted on the second rotating shaft 04, and the toy head 02 is detachably mounted on the mounting head 08. Toy head 02 is changed as required, and experience is higher.

In this embodiment, the second driving member 03 may be a motor or a servo motor.

In other embodiments, the second rotational shaft 04 may be the output shaft of the second driving member 03, and the toy head 02 is mounted directly on the second rotational shaft 04.

It should be understood that the toy head 02 may mimic the head of an animal or may be freely designed, and that colors or graphics may be applied to the toy head 02 to increase playability.

In this embodiment, optionally, the first rotating shaft 004 and the second rotating shaft 04 are arranged perpendicularly. Obviously, in other embodiments, the first rotation shaft 004 and the second rotation shaft 04 may not be perpendicular.

The bouncing rotary toy provided by the embodiment has the advantages that the toy head 02 is mounted on the mounting head 08, the toy head 02 can bounce together with the bouncing piece 002 and can also rotate together with the second rotating shaft 04, and the toy head 02 can independently realize one of two functions of bouncing and rotating and can also simultaneously realize two functions of bouncing and rotating. And toy head 02 when realizing the function of bouncing, toy head 02 pops out rapidly, can realize reciprocating bounce under the elastic force effect of elastic component 006 after popping out, and the action is more lifelike, and the action is more diversified, and the object-to-be-played nature is higher.

It should be noted that, the first driving element 003 and the second driving element 03 can be both configured as motors, and the first driving element 003 and the second driving element 03 can be powered by batteries, and it should be understood that the batteries can be rechargeable batteries; the first driving member 003 and the second driving member 03 can also be powered by mains electricity.

The opening and closing of the first driving element 003 and the second driving element 03 may be remotely controlled or may be controlled by a switch provided on the base 001. It should be understood that the first driving member 003 and the second driving member 03 may be controlled simultaneously or separately.

The above description is only a preferred embodiment of the present disclosure and is not intended to limit the present disclosure, and various modifications and changes may be made to the present disclosure by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present disclosure should be included in the protection scope of the present disclosure.

Industrial applicability:

in conclusion, the present disclosure provides a bouncing device and a bouncing rotary toy, the head of which bounces rapidly and the experience degree is high.

Claims (19)

1. A bouncing device is characterized by comprising a base, a bouncing piece, a first driving piece, a first rotating shaft, a flexible winding piece and an elastic piece, wherein the first driving piece is installed on the base, the first driving piece is connected to the first rotating shaft, one end of the flexible winding piece is fixed on the first rotating shaft, and the other end of the flexible winding piece is fixed on the bouncing piece; the base is connected with the bouncing piece through the elastic piece, and the elastic piece enables the bouncing piece to have the tendency of moving away from the base;

the bouncing device also comprises a locking mechanism with a braking state and a releasing state, and the locking mechanism is arranged on the base; the braking state means that the locking mechanism allows the first rotating shaft to rotate along a first rotating direction so that the flexible winding piece is wound on the first rotating shaft, and simultaneously limits the first rotating shaft to rotate along a second rotating direction; the releasing state refers to that the locking mechanism releases the brake on the first rotating shaft, so that the flexible winding piece pulls the first rotating shaft to rotate along the second rotating direction under the action of the elastic force of the elastic piece;

wherein the first rotational direction is opposite the second rotational direction.

2. The bouncing apparatus as claimed in claim 1, wherein the base comprises a guide rod, the bouncing member has a sliding hole, the guide rod is inserted into the sliding hole, and the guide rod and the bouncing member are slidably engaged with each other along a central axis of the sliding hole.

3. The bouncing device of claim 2 wherein the guide bar is provided with a mounting channel extending through both ends of the guide bar along the length thereof, and the flexible winding member is disposed through the mounting channel.

4. The bouncing device of any one of claims 2-3 wherein the base further comprises a bottom housing, the guide bar is mounted to the bottom housing, the first driving member is mounted within the bottom housing, and the flexible winding member is coupled to the bouncing member after passing through the bottom housing.

5. The bouncer device of claim 4, wherein the bottom housing comprises a housing having a mounting slot and a cover plate mounted on the housing, the cover plate covering the slot opening of the mounting slot, the cover plate and the housing together defining a receiving chamber for receiving the first drive member.

6. The bouncing device as claimed in any one of claims 2 to 5, wherein the bouncing member is provided with a stopper protrusion on an inner peripheral wall surrounding the sliding hole, the stopper protrusion protrudes inward from the inner peripheral wall in a radial direction of the sliding hole, the elastic member is located in the sliding hole, one end of the elastic member abuts on an end of the guide rod inserted into the sliding hole, and the other end of the elastic member abuts on the stopper protrusion.

7. The bouncing apparatus of claim 6 wherein the bouncing member comprises a first housing half and a second housing half, the first housing half being snap-fit to the second housing half, the first housing half and the second housing half together defining the sliding aperture.

8. The bouncer device of claim 1, wherein the locking mechanism comprises a main gear, a snap gear, and a swing assembly; the main gear is mounted on the first rotating shaft, the clamping gear is mounted on the swinging assembly, the main gear is meshed with the clamping gear, and the first driving piece is connected to the swinging assembly; the swing assembly is provided with a first working position and a second working position, and when the swing assembly is located at the first working position, the first driving piece transmits torque to the clamping gear through the swing assembly so as to drive the main gear to rotate along the first rotating direction; when the swing assembly is located at the second working position, the clamping gear is separated from the main gear, so that the flexible winding piece pulls the first rotating shaft to rotate along the second rotating direction under the action of the elastic force of the elastic piece.

9. The bouncer device of claim 8, wherein the locking mechanism further comprises a first torsion spring and a power input gear, the swing assembly comprises a swing seat, a swing shaft, a transmission gear, a pawl and a second torsion spring, the swing shaft is mounted on the base, the first torsion spring is sleeved outside the swing shaft, the swing seat is mounted on the base through the first torsion spring, and the first torsion spring causes the swing seat to have a tendency to rotate relative to the main gear to maintain the swing assembly in the first working position; the transmission gear is mounted on the swinging seat, a rotating shaft of the transmission gear is coaxial with the swinging shaft, the transmission gear is meshed with the clamping gear, the clamping jaw is mounted on the swinging seat through the second torsion spring, the second torsion spring enables the clamping jaw to have a movement trend towards the clamping gear to enable the clamping jaw to be clamped on the clamping gear, and the clamping jaw is configured to limit the clamping gear to rotate along the first rotating direction and simultaneously allow the clamping gear to rotate along the second rotating direction; the power input gear is mounted on the base and meshed with the transmission gear, the first driving piece is connected to the power input gear to drive the power input gear to rotate, and when the power input gear rotates along the first rotating direction, the transmission gear rotates along the second rotating direction and drives the swinging seat to swing away from the main gear, so that the locking mechanism is in the releasing state; when the power input gear rotates along the second rotating direction, the power input gear transmits torque to the main gear sequentially through the transmission gear and the clamping gear, and the locking mechanism is enabled to be in the braking state.

10. The bouncer of claim 9, wherein the swing base comprises a first mounting plate, a second mounting plate, a first mounting shaft, a second mounting shaft and a third mounting shaft, the first mounting plate is disposed opposite to the second mounting plate, two ends of the first mounting shaft are mounted on the first mounting plate and the second mounting plate, two ends of the second mounting shaft are mounted on the first mounting plate and the second mounting plate, two ends of the third mounting shaft are mounted on the first mounting plate and the second mounting plate, the latch gear is mounted on the first mounting shaft, the transmission gear is mounted on the second mounting shaft, and the pawl is mounted on the third mounting shaft; the swing shaft is mounted on the first mounting plate.

11. The bouncing device of any one of claims 9-10, wherein a stop portion is disposed on the base, the swinging seat abuts against the stop portion under the action of the first torsion spring, and the stop portion is configured to limit the swinging seat from swinging in a direction approaching the main gear.

12. The bouncer according to any one of claims 9-11, wherein the bouncer further comprises a belt transmission mechanism and a gear transmission mechanism, the belt transmission mechanism comprises a driving pulley, a driven pulley and a transmission belt, the driving pulley is mounted on the first driving member, the driven pulley is mounted on the base, and the transmission belt is wound around the driving pulley and the driven pulley; the output end gear of the gear transmission mechanism is coaxially arranged with the driven belt wheel, and the input end gear of the gear transmission mechanism is meshed with the power input gear.

13. The bouncer of any one of claims 8-12, further comprising a mounting case, wherein the locking mechanism is mounted in the mounting case, wherein the first drive member is mounted on the mounting case, and wherein the mounting case is mounted on the base.

14. The bouncing device of any one of claims 1-13 wherein the bouncing device further comprises a bobbin that is disposed outside the first rotating shaft, the bobbin being in circumferentially limited connection with the first rotating shaft, and one end of the flexible winding member being secured to the bobbin.

15. A bouncing rotation toy comprising a toy head, a second driving member and a bouncing device according to any one of claims 1-14, wherein the second driving member is mounted on the bouncing member, and wherein the second driving member is provided with a second rotation axis configured to mount the toy head.

16. The bouncing rotary toy as claimed in claim 15, further comprising a mounting plate, wherein the mounting plate is provided with mounting holes and mounting notches communicated with the mounting holes, the bouncing element is provided with bearing protrusions and clamping protrusions, the bearing protrusions and the clamping protrusions both protrude out of the outer peripheral surface of the bouncing element along the radial direction of the bouncing element, the bearing protrusions and the clamping protrusions are arranged at intervals along the bouncing direction of the bouncing element, and the mounting plate is clamped between the bearing protrusions and the clamping protrusions.

17. The bouncing rotary toy of claim 16 wherein the mounting plate is provided with a limiting protrusion structure and a toggle member, the toggle member is mounted on the mounting plate, and the engaging protrusion is engaged between the limiting protrusion structure and the toggle member.

18. The bouncing rotation toy of any one of claims 15-17 further comprising a gear box, wherein the second drive member is coupled to the second rotational shaft via the gear box, and wherein the gear box is mounted to the bouncing member.

19. The bouncing rotation toy of claim 18 further comprising a mounting head mounted to the second pivot axle, the toy head being removably coupled to the mounting head.

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