CN220478106U - Deformation toy - Google Patents

Abstract

The utility model discloses a deformation toy, which comprises: the device comprises a machine base and a machine body, wherein a driving assembly is arranged on the machine base; the machine body is connected with the machine base and has an unfolding state and a folding state; the driving assembly is in transmission connection with the machine body, and the driving assembly is suitable for driving the machine body to be switched from the unfolding state to the folding state. According to the deformation toy disclosed by the embodiment of the utility model, the machine base can improve the structural stability of the deformation toy, and the switching of the machine body from the unfolding state to the folding state is realized through the driving assembly, so that the deformation of the deformation toy is simple and quick, the storage of the deformation toy is convenient, and the use experience of the deformation toy is improved.

Description

Deformation toy

Technical Field

The utility model relates to the technical field of toys, in particular to a deformation toy.

Background

The transformable toy is a transformable toy, is generally composed of movable parts, and can be combined together in various modes, in the related art, in the switching process of different states, a plurality of parts are required to be folded or unfolded respectively, so that the state of the transformable toy is switched to be complex, and the use experience of a user is reduced.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems in the related art to some extent. Therefore, the utility model aims to provide the transformable toy which is simple and quick to deform, convenient to store and stable in structure.

The deformation toy comprises a machine base and a machine body, wherein a driving assembly is arranged on the machine base, and the machine body is connected with the machine base and has an unfolding state and a folding state; the driving assembly is in transmission connection with the machine body, and the driving assembly is suitable for driving the machine body to be switched from the unfolding state to the folding state.

According to the deformation toy disclosed by the embodiment of the utility model, the machine base can provide support and fixation for the machine body, so that the deformation toy can have a stable state in different deformation states, the structural stability of the deformation toy is improved, the deformation of the deformation toy is simple and quick by the driving assembly, and the deformation toy is convenient to store.

In addition, the transformable toy according to the above embodiment of the present utility model may further have the following additional technical features:

in some embodiments, the drive assembly comprises: the rotating piece is in transmission connection with the machine body; the driving member is in driving connection with the rotating member and is configured and adapted to drive the rotating member to switch the body from the unfolded state to the folded state.

In some embodiments, the driving member has a first position and a second position, the driving member is in the first position when the body is in the unfolded state, the driving member is in the second position when the body is in the folded state, and the rotating member can drive the body to switch from the unfolded state to the folded state when the driving member moves from the first position to the second position.

In some embodiments, the fuselage comprises: the first deformation piece, the second deformation piece and the first transmission assembly are rotatably connected with the base and are in transmission connection with the driving assembly; the second deformation piece is rotatably connected with the first deformation piece; the first transmission assembly is respectively connected with the base, the first deformation piece and the second deformation piece and is used for linkage of the first deformation piece and the second deformation piece to synchronously fold.

In some embodiments, the fuselage further comprises: the first reset piece is respectively connected with the base and the first deformation piece and has elastic force for driving the first deformation piece to be unfolded; and/or a second restoring member, which is connected to the first deforming member and the second deforming member, respectively, and has an elastic force for driving the second deforming member to expand.

In some embodiments, the housing has a first latch hook releasably latching the fuselage in the folded state, wherein the first deformation and the second deformation fold over the housing and are latched by the first latch hook when the fuselage is in the folded state.

In some embodiments, the first transmission assembly includes: the first transmission structure is arranged on the first deformation piece in a telescopic way, one end of the first transmission structure is connected with the base in a sliding way, and the first deformation piece is suitable for driving the first transmission structure to stretch when rotating; the second transmission structure is rotatably arranged on the first deformation piece and is respectively in transmission connection with the first transmission structure and the second deformation piece.

In some embodiments, the first transmission assembly further comprises: the third transmission structure is rotatably arranged on the first deformation piece and comprises a first gear and a second gear which are coaxially and fixedly connected, wherein the first transmission structure is provided with a first rack, the second transmission structure is provided with a third gear, the first rack is meshed with the first gear, the third gear is meshed with the second gear, and the number of teeth of the third gear is smaller than that of the second gear.

In some embodiments, the base is provided with a sliding groove, and the end part of the first transmission structure is slidably matched with the sliding groove, and the sliding groove extends from one end to the other end around the rotation center of the second transmission structure and gradually moves away from the rotation center of the second transmission structure.

In some embodiments, the fuselage further comprises: the third deformation piece is rotatably connected with the second deformation piece; the second transmission assembly is respectively connected with the second deformation piece and the third deformation piece and is used for linkage of the third deformation piece and the second deformation piece to synchronously fold.

In some embodiments, the fuselage further comprises: and the third reset piece is respectively connected with the second deformation piece and the third deformation piece and has elastic force for driving the third deformation piece to fold.

In some embodiments, the second transmission assembly includes: the fourth transmission structure, the fifth transmission structure and the sixth transmission structure are fixed at the relative positions of the fourth transmission structure and the first deformation piece; the fifth transmission structure is telescopically arranged on the second deformation piece and is in transmission connection with the fourth transmission structure; the sixth transmission structure is rotatably arranged on the second deformation piece and is respectively in transmission connection with the fifth transmission structure and the third deformation piece.

In some embodiments, the fourth transmission structure is provided with a fourth gear, one end of the fifth transmission structure is provided with a second rack, the other end of the fifth transmission structure is provided with a third rack, the sixth transmission structure is provided with a fifth gear, wherein the fourth gear is meshed with the second rack, the third rack is meshed with the fifth gear, and the fifth gear is suitable for driving the third deformation piece to be unfolded.

In some embodiments, the fuselage further comprises: and the fourth deformation piece is connected with the sixth transmission structure and is fixed in relative position.

In some embodiments, a first rotation axis is arranged between the first deformation piece and the base, a second rotation axis is arranged between the second deformation piece and the first deformation piece, a third rotation axis is arranged between the third deformation piece and the second deformation piece, the first rotation axis is parallel to the second rotation axis, and the second rotation axis is perpendicular to the third rotation axis; and/or, in the folded state, the first deformation member is folded on the stand, and the second deformation member is folded with the first deformation member; and/or, in the folded state, the third deforming member is folded with the second deforming member; and/or, in the unfolded state, the first deformation piece extends along the up-down direction, the lower end of the first deformation piece is connected with the base, the second deformation piece extends along the up-down direction, and the lower end of the second deformation piece is connected with the upper end of the first deformation piece; and/or, in the unfolded state, the third deformation piece extends along the up-down direction, the upper end of the third deformation piece is connected with the upper end of the second deformation piece, and the lower end of the third deformation piece is spaced from the second deformation piece along the left-right direction.

Drawings

Fig. 1 is a schematic view of a transformable toy of an embodiment of the present utility model, wherein the transformable toy is in a deployed state.

Fig. 2 is a schematic view of a transformable toy of an embodiment of the present utility model, wherein the transformable toy is in a folded state.

Fig. 3 is a schematic view of a transformable toy of another embodiment of the present utility model, wherein the transformable toy is in a deployed state.

Fig. 4 is a schematic view of a transformable toy of another embodiment of the present utility model, wherein the transformable toy is in a folded state.

Fig. 5 is a schematic view of a transformable toy of an embodiment of the present utility model.

Fig. 6 is a schematic diagram of a transformable toy of an embodiment of the present utility model.

Fig. 7 is a schematic view of a transformable toy in which the body is hidden, according to an embodiment of the present utility model.

Fig. 8 is an exploded schematic view of a toy deformation according to an embodiment of the present utility model, in which the body is hidden.

Fig. 9 is a schematic view of a transformable toy of an embodiment of the present utility model in which the fuselage is hidden.

Fig. 10 is a schematic view of a transformable toy of an embodiment of the present utility model.

Fig. 11 is a schematic view of a transformable toy of an embodiment of the present utility model.

Fig. 12 is a schematic view of a transformable toy of an embodiment of the present utility model.

Fig. 13 is a schematic view of a transformable toy of an embodiment of the present utility model.

Fig. 14 is a schematic view of a transformable toy of an embodiment of the present utility model.

Fig. 15 is an enlarged schematic view at circle a in fig. 14.

Fig. 16 is a schematic diagram of a transformable toy of an embodiment of the present utility model.

Fig. 17 is an enlarged schematic view at circle B in fig. 16.

Fig. 18 is a schematic diagram of a transformable toy of an embodiment of the present utility model.

Fig. 19 is a schematic view of a transformable toy of an embodiment of the present utility model in which the fuselage is hidden.

Reference numerals:

deformation toy 1000, machine body 100, machine base 10, first lock hook 111, chute 12, second lock hook 112, roller 171, cam 172, transmission mechanism 173, first transmission member 18, fourth rack 13, first toggle tooth 131, fourth reset member 141, fifth reset member 142, magnetic attraction structure 15, seventh transmission structure 16, first transmission portion 161, second transmission portion 162, machine body 20, first deformation member 211, second deformation member 212, third deformation member 213, fourth deformation member 214, first transmission assembly 22, first transmission structure 221, first rack 2211, the second transmission structure 222, the third gear 2222, the third transmission structure 223, the first gear 2231, the second gear 2232, the second transmission assembly 23, the fourth transmission structure 231, the fourth gear 2311, the fifth transmission structure 232, the second rack 2321, the third rack 2322, the sixth transmission structure 233, the fifth gear 2331, the first link mechanism 2332, the first reset element 241, the second reset element 242, the third reset element 243, the driving assembly 30, the rotating element 31, the driving element 32, the second toggle tooth 331, the rotating portion 50, the slider 51, the unlocking element 500.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present utility model and should not be construed as limiting the utility model.

Referring to fig. 1 to 4, a transformable toy 1000 according to an embodiment of the present utility model includes a base 10 and a body 20, the body 20 being connected to the base 10 and having an unfolded state and a folded state, in other words, the body 20 being deformable, the body 20 being unfolded or folded on the base 10, and the base 10 being provided to support and fix the body 20, the transformable toy 1000 being capable of having a stable state in different transformation states, thereby improving structural stability of the transformable toy 1000. The drive assembly 30 is arranged on the machine base 10 and is in transmission connection with the machine body 20, the drive assembly 30 is suitable for driving the machine body 20 to switch from an unfolding state to a folding state, deformation of the deformation toy 1000 is simple and rapid, storage of the deformation toy 1000 is convenient, the drive assembly 30 is arranged on the machine base 10, the machine base 10 is a relatively fixed component, structural stability of the drive assembly 30 can be improved, and operation is convenient.

It will be appreciated that the transformable toy 1000 generally needs to be placed on a relatively flat plane, and the toy can be stably stood, and by setting the stand 10, the transformable toy 1000 is not easy to topple over in different states, and can adapt to different playing environments, so that the playing experience of a user is improved.

According to the deformation toy 1000 of the embodiment of the utility model, the frame 10 can promote the structural stability of the deformation toy 1000, and the switching of the body 20 from the unfolded state to the folded state is realized through the driving component 30, so that the deformation of the deformation toy 1000 is simple and quick, and the deformation toy 1000 is convenient to store.

The body 20 is connected with the stand 10, and the body 20 has an unfolding state and a folding state, the body 20 may include a plurality of deformation pieces, the number of the deformation pieces may be two, three, four, etc., and may be specifically adjusted according to the shape of the toy, for example, the shape of the deformation toy 1000 may be a robot, an animal, a vehicle, etc., the unfolding state may be a robot, an animal, etc., the folding state may be a toy car, and when in the folding state, the deformation of the toy may be realized, so that the toy has multiple playing methods, and the toy may be conveniently stored and carried. Of course, the above-described state of the transformable toy 1000 is merely illustrative, and is not intended to limit the scope of the present application.

The driving assembly 30 is connected to the base 10, and the driving assembly 30 may be disposed in different forms, and may be disposed at different positions of the base 10, for example, the driving assembly 30 may be disposed in a form of a spring plate, the body 20 may be driven to switch from an unfolded state to a folded state by turning the spring plate, or a structure such as a rotating part or a spring may be disposed, and the body 20 may be driven to switch from the unfolded state to the folded state by turning the rotating part or the spring, so that the deformation toy 1000 may be deformed and stored, and the storage of the deformation toy 1000 may be more convenient, where the driving assembly 30 may be disposed at the bottom of the base 10, or disposed on the left and right sides of the base 10, or disposed above the base 10, and may be specifically adjusted according to the shape of the deformation toy 1000, and the structure related to the driving assembly 30 described above is merely for illustration, and is not a limitation of the protection scope of the present application, and the driving assembly 30 may be disposed in other forms.

Referring to fig. 5 and 10, in some embodiments of the present utility model, the driving assembly 30 may include a rotation member 31 and a driving member 32, the rotation member 31 may be in driving connection with the body 20, and the driving member 32 is in driving connection with the rotation member 31 and configured to be adapted to drive the rotation member 31 to fold the body 20. Specifically, the driving element 32 can be rotated to drive the rotating element 31 to move so as to drive the body 20 to fold, and the driving element 32 is arranged to facilitate the application of deforming force to the deformed toy 1000 by a user and facilitate the folding of the deformed toy 1000.

The driving member 32 and the rotating member 31 may be a gear transmission, a rack transmission, etc., and the transmission efficiency is high and the stability is good. The rotation member 31 may be keyed, pinned, threaded, etc. to the body 20 to facilitate the stable rotation of the body 20 by the drive assembly 30. Preferably, the rotating member 31 is in key connection with the body 20, so that the rotating member 31 and the body 20 are well connected and fastened, the stability and reliability of connection are improved, and larger force and torque can be borne, so that the rotating member 31 can stably drive the body 20 to fold.

Further, the driving element 32 may have a first position and a second position, when the body 20 is in the unfolded state, the driving element 32 may be located at the first position, when the body 20 is in the folded state, the driving element 32 may be located at the second position, and when the driving element 32 moves from the first position to the second position, the rotating element 31 may be driven to fold the body 20, and by moving the driving element 32, the folding of the body 20 is achieved, so that the folding of the body 20 is convenient and quick, and further the storage of the deformed toy 1000 is facilitated.

Wherein the drive assembly 30 may be configured differently, the drive member 32 may have different angles in the first and second positions, and the different configurations of the drive assembly 30 in some embodiments of the utility model are described below in connection with the figures.

Example 1

Referring to fig. 5, the driving assembly 30 includes a rotating member 31 and a driving member 32, the driving member 32 may be a spring plate, the rotating member 31 is rotatably disposed on the base 10 and is in transmission connection with the body 20, the driving member 32 is rotatably connected with the base 10 and is configured to be adapted to drive the rotating member 31 to fold the body 20, and the driving member 32 is in transmission engagement with the rotating member 31 when moving from the first position to the second position and drives the rotating member 31 to fold the body 20.

Referring to fig. 5 and 6, alternatively, the driving member 32 may be stacked on the bottom surface of the housing 10 in the first and second positions, and the driving member 32 may be disposed under the housing 10 in the front-rear direction in a reversible manner. When the body 20 is in the unfolded state, the driving element 32 is located at the first position, at this time, the driving element 32 can be stacked at a position forward of the bottom surface of the stand 10, and when the driving element 32 is turned backward to a position backward of the bottom surface of the stand 10, the body 20 is driven to fold. In other words, the driving member 32 rotates 180 ° relative to the second position in the first position, so that the deformation toy 1000 is compact in structure due to the lamination of the driving member 32 on the bottom surface of the base 10 in both the first position and the second position, and the base 10 is relatively fixed, so that the structural stability of the driving member 32 can be improved.

Referring to fig. 7, 8 and 9, optionally, a fourth rack 13 may be provided on the stand 10, where the fourth rack 13 is movably provided on the stand 10 and is in transmission connection with the rotating member 31, a first toggle tooth 131 may be provided on the fourth rack 13, a second toggle tooth 331 may be provided on the driving member 32, and when the driving member 32 moves from the first position to the second position, the first toggle tooth 131 is in transmission fit with the second toggle tooth 331 so as to drive the machine body 20 to fold. For example, when the machine body 20 needs to be folded, the driving member 32 can be turned backwards, and in the turning process, the first toggle teeth 131 and the second toggle teeth 331 are driven to drive the fourth rack 13 to move forwards, the fourth rack 13 drives the rotating member 31 to rotate, and the rotating member 31 drives the machine body 20 to rotate, so that the machine body 20 is folded. By providing the fourth rack 13 between the driving member 32 and the rotating member 31, and by means of gear transmission, the reliability of the transmission structure can be improved.

Referring to fig. 6 to 9, alternatively, the stand 10 may be provided with a fourth restoring member 141, and the fourth restoring member 141 is connected to the driving member 32 and has an elastic force for pushing the driving member 32 to move toward the first position. Specifically, when the deformation toy 1000 is switched from the folded state to the deformed state, the driving member 32 rotates from the second position to the first position, by setting the fourth reset member 141, the driving member 32 can be conveniently pushed to move to the first position, and the driving member 32 can be driven to stably maintain at the first position, so that the structural stability of the driving member 32 is improved, when an external force larger than the elastic force is applied to the driving member 32, the driving member 32 can be turned over to move to the second position to drive the body 20 to fold, and the unfolding and folding states of the body 20 are more smoothly switched by setting. The base 10 may further include a second latch hook 112, where the second latch hook 112 may have a locking position and an unlocking position to releasably lock the driving member 32 in the second position, where the driving member 32 moves from the first position to the second position, and drives the body 20 in the folded state, where the driving member 32 may be engaged with the second latch hook 112, and where the second latch hook 112 is located in the locking position to stably maintain the driving member 32 in the second position, where the second latch hook 112 may release the driving member 32 when in the unlocking position, where the driving member 32 is pushed to move toward the first position and where the driving member 32 may be stably maintained in the first position under the action of the fourth reset member 141. Wherein the fourth restoring member 141 may be a spring.

Optionally, the stand 10 may further include a seventh transmission structure 16 and a fifth reset element 142, where the seventh transmission structure 16 is movable to drive the second latch hook 112 to the unlocked position, and the fifth reset element 142 is connected to the seventh transmission structure 16 and adapted to elastically drive the second latch hook 112 to the locked position. Specifically, the driving member 32 is locked by the second latch hook 112 when in the second position, and the seventh transmission structure 16 can move backward, at this time, the second latch hook 112 is driven to move backward, the locking of the driving member 32 is released, and the driving member 32 is pushed to move to the first position under the action of the fourth reset member 141. When the locking of the driving member 32 is released, the seventh transmission structure 16 is restored to the original position under the action of the fifth reset member 142, and drives the second latch hook 112 to the locking position, so as to prepare for the next locking of the driving member 32 by the second latch hook 112. Wherein the fifth restoring member 142 may be a spring.

Example 2

Referring to fig. 10, the driving assembly 30 includes a rotation member 31 and a driving member 32, the driving member 31 may be a rotation portion, the driving member 32 is rotatably disposed on the base 10 and configured to be suitable for manual driving or externally connecting with a driving module, the body 20 is in transmission connection with the driving member 32 and is suitable for being driven to be folded by the driving member 32, in other words, the body 20 may be directly driven to be folded by rotating the driving member 32, or the body 20 may be folded by externally connecting with the driving member 32, and the body 20 is driven to be folded by providing the driving member 32, so that the user can conveniently operate the folding of the body 20.

Wherein the driver 32 has a first position and a second position, the driver 32 is in the first position when the body is in the extended state, and the driver 32 is in the second position when the body is in the collapsed state, e.g., the driver 32 is rotatable 90 ° about the center of rotation of the driver 32 in the first position relative to the second position.

Optionally, the rotating member 31 may be connected with the body 20 by a key, and the rotating member 31 can synchronously drive the body 20 to fold, specifically, the driving member 32 drives the rotating member 31 to rotate, and the rotating member 31 drives the body 20 to fold, so that the reliability and stability of the transmission structure of the deformation toy 1000 are improved by setting the rotating member 31.

Referring to fig. 10, optionally, a gear transmission structure may be provided between the driving member 32 and the rotating member 31, so as to improve smoothness of the deformed toy 1000 when the deformed toy is switched from the unfolded state to the folded state, and the gear transmission structure has high transmission efficiency and good stability, so that the driving member 32 can stably drive the deformed toy 1000 to fold, and improve use experience of a user. For example, a first transmission member 18 may be disposed between the driving member 32 and the rotating member 31, where the first transmission member 18 and the driving member 32 may be in a key connection, and the first transmission member 18 and the rotating member 31 are in gear transmission, so that the first transmission member 18 can be driven to rotate when the driving member 32 is rotated, the first transmission member 18 drives the rotating member 31 to rotate, and further drives the machine body 20 to fold.

Referring to fig. 10, alternatively, the driving member 32 may include two driving members disposed at both left and right sides of the housing 10, and the two driving members 32 are in driving connection with the same rotating member 31. When the machine body 20 needs to be folded, the machine body 20 can be driven to be folded by rotating any one driving piece 32, meanwhile, the driving piece 32 can be externally connected with a driving handle, the driving handle can be simultaneously connected with two driving pieces 32, and when the driving handle is rotated, the two driving pieces 32 are synchronously driven to rotate, so that the machine body 20 is driven to be folded, the machine body 20 is folded conveniently and rapidly, and the strength is saved.

Alternatively, the driving member 32 may include a slider 51, and the slider 51 is configured in an elongated shape extending in a direction perpendicular to the rotation center axis of the driving member 32. The sliding block 51 is convenient for holding the driving piece 32 by a human hand to operate, and the driving piece 32 can be conveniently connected with a driving module in an external mode through the sliding block 51, so that the adaptability of the driving piece 32 is improved.

Optionally, the center of rotation of the driving member 32 passes through the center of the slider 51, improving smoothness during rotation of the driving member 32.

Referring to fig. 11 and 12, in some embodiments of the present utility model, the body 20 may include a first deforming member 211, a second deforming member 212, and a first transmission assembly 22, where the first deforming member 211 is rotatably connected to the base 10 and is in transmission connection with the rotating member 31, the second deforming member 212 is rotatably connected to the first deforming member 211, and the first transmission assembly 22 is respectively connected to the base 10, the first deforming member 211, and the second deforming member 212, and is used for the first deforming member 211 and the second deforming member 212 to be synchronously folded, in other words, the first deforming member 211 and the second deforming member 212 can be synchronously linked by the transmission assembly to realize synchronous folding, thereby realizing one-key folding of the body 20, making state switching and storage of the deformed toy 1000 simple and convenient, and improving user experience.

The driving component 30 is in driving connection with the first deforming member 211, and the driving component 30 and the first deforming member 211 may be in key connection, so that the connection tightness between the driving component 30 and the first deforming member 211 is good, the stability and reliability of connection are improved, and the machine body 20 is stably driven to fold.

Referring to fig. 13, in some embodiments of the present utility model, the body 20 may include a first restoring member 241, the first restoring member 241 being connected to the housing 10 and the first deforming member 211, respectively, and having an elastic force driving the first deforming member 211 to expand, specifically, the body 20 has an expanded state and a folded state, by providing the first restoring member 241, the body 20 may be stabilized in the expanded state, the structural stability of the deformed toy 1000 may be improved, and the switching of the body 20 from the expanded state to the folded state may be facilitated, when the driving assembly 30 moves, the driving assembly 30 applies a force to the first deforming member 211, the applied force is greater than the elastic force of the first restoring member 241, and the first deforming member 211 is driven to rotate, and the body 20 is switched from the expanded state to the folded state. The first restoring member 241 may have a spring or the like.

Referring to fig. 10, in some embodiments of the present utility model, the body 20 may include a second restoring member 242, and the second restoring member 242 may be connected to the first deforming member 211 and the second deforming member 212, respectively, and have an elastic force for driving the second deforming member 212 to expand, specifically, the body 20 has an expanded state and a folded state, by providing the second restoring member 242, the body 20 may be stably maintained in the expanded state, structural stability of the deformed toy 1000 may be improved, and switching of the body 20 from the expanded state to the folded state may be facilitated, and when the driving assembly 30 moves, the first deforming member 211 is driven to fold and the first driving assembly 22 is driven to rotate, and the first driving assembly 22 applies a force to the second deforming member 212, which is greater than the elastic force of the second restoring member 242, so as to drive the second deforming member 212 to rotate, thereby switching of the body 20 from the expanded state to the folded state may be realized. The second restoring member 242 may have a spring or the like.

Referring to fig. 12 and 13, in some embodiments of the present utility model, the frame 10 may have a first latch hook 111 thereon, and the first latch hook 111 may releasably latch the body 20 in a folded state, wherein when the body 20 is in the folded state, the first deformation member 211 and the second deformation member 212 are folded on the frame 10 and are latched by the first latch hook 111, so that after the body 20 is folded, the body 20 can be latched by the first latch hook 111, so that the body 20 can be stably maintained in the folded state, and structural stability of the deformation toy 1000 is improved. When the transformable toy 1000 needs to be switched to the unfolding state, the first lock hook 111 can be released, and in combination with the previous embodiment, the transformable toy 1000 can be provided with the first reset piece 241 and/or the second reset piece 242, and after the first lock hook 111 releases the lock on the body 20, the reset piece can drive the body 20 to unfold, so that the body 20 is stably maintained in the unfolding state. The transformable toy 1000 can be folded by one key or unfolded by one key, and after different states are switched, the transformable toy can be stably maintained in the corresponding state.

Referring to fig. 12, in some embodiments of the present utility model, the first transmission assembly 22 may include a first transmission structure 221 and a second transmission structure 222, where the first transmission structure 221 is telescopically disposed on the first deformation member 211, and one end of the first transmission structure 221 may be slidably connected to the base 10, the first deformation member 211 is adapted to drive the first transmission structure 221 to stretch and retract when rotating, and the second transmission structure 222 is rotatably disposed on the first deformation member 211 and is respectively in transmission connection with the first transmission structure 221 and the second deformation member 212, specifically, the second transmission structure 222 and the first transmission structure 221 may be in gear transmission, the second transmission structure 222 and the second deformation member 212 may be in key connection, the driving assembly 30 drives the first deformation member 211 to rotate and drives the first transmission structure 221 to stretch and retract, the first transmission structure 221 drives the second transmission structure 222 to rotate, and the second transmission structure 222 drives the second deformation member 212 to rotate, so as to implement linkage of the first deformation member 211 and the second deformation member 212 through the second transmission structure 222, thereby implementing synchronous folding of the first deformation member 211 and the second deformation member 212.

Referring to fig. 12, the base 10 may be provided with a sliding slot 12, and an end portion of the first transmission structure 221 may be slidably engaged with the sliding slot 12, for example, a rack may be provided on the first transmission structure 221, and an end portion of the rack may be slidably engaged with the sliding slot 12, so that when the first deformation member 211 rotates on the base 10, the first transmission structure 221 stretches over the first deformation member 211. In addition, the first transmission structure 221 is in transmission connection with the second transmission structure 222, and may be in a gear-rack transmission manner, for example, teeth may be disposed on the other end of the rack, a gear may be disposed on the second transmission structure 222, the other end of the rack may be meshed with the second transmission structure 222, and the chute 12 may extend from one end to the other end around the rotation center of the second transmission structure 222 and gradually away from the rotation center of the second transmission structure 222. By providing the chute 12 on the base 10, the first transmission structure 221 moves along a predetermined direction, so as to avoid deviation of the moving direction and improve the stability of the first transmission assembly 22 during the moving process.

Referring to fig. 14 to 17, in some embodiments of the present utility model, the first transmission assembly 22 may further include a third transmission structure 223, the third transmission structure 223 may be rotatably disposed on the first deforming member 211, referring to fig. 15, the third transmission structure 223 may include a first gear 2231 and a second gear 2232 coaxially and fixedly connected, wherein the first transmission structure 221 may have a first rack 2211 thereon, referring to fig. 17, the second transmission structure 222 may have a third gear 2222 thereon, referring to fig. 15, the first rack 2211 is engaged with the first gear 2231, the third gear 2222 is engaged with the second gear 2232, and the number of teeth of the third gear 2222 is smaller than the number of teeth of the second gear 2232. In other words, the third transmission structure 223 is in transmission connection with the first transmission structure 221 and the second transmission structure 222, and the transmission ratio can be changed by setting the third transmission structure 223, specifically, the first gear 2231 and the second gear 2232 which are coaxially and fixedly connected are used as transition teeth between the first transmission structure 221 and the second transmission structure 222 and are meshed with each other, so that the effect of reducing speed and increasing torque can be achieved, that is, the rotation speed of the third gear 2222 is reduced, and then the output torque of the second transmission structure 222 is increased, and the phenomenon that the second deformation member 212 is not smooth due to insufficient force in the rotation process is avoided, so that the rotation of the second deformation member 212 can be smoothly driven when the first deformation member 211 rotates, and the stability of the machine body 20 in folding is improved.

Specifically, the driving assembly 30 rotates to drive the first deforming member 211 to rotate backward, the first deforming member 211 simultaneously drives the first transmission structure 221 to slide forward along the chute 12 on the stand 10, the first transmission structure 221 simultaneously drives the third transmission structure 223 (the first gear 2231 and the second gear 2232) to rotate, the third transmission structure 223 transmits force to drive the second transmission structure 222 to rotate, and the second transmission structure 222 rotates to drive the second deforming member 212 to rotate, so that the first deforming member 211 and the second deforming member 212 are synchronously linked and folded on the stand 10.

Referring to fig. 14 to 17, in some embodiments of the present utility model, the body 20 may further include a third deforming member 213 and a second transmission assembly 23, the third deforming member 213 being rotatably coupled to the second deforming member 212, the second transmission assembly 23 being respectively coupled to the second deforming member 212 and the third deforming member 213 for the third deforming member 213 and the second deforming member 212 to be interlocked for synchronous folding. Specifically, when the second deforming member 212 rotates, the second transmission assembly 23 is driven to move, and then the third deforming member 213 is driven to rotate, so that linkage synchronous folding of the third deforming member 213 and the second deforming member 212 is realized.

By arranging the second transmission assembly 23, the linkage of the second deformation element 212 and the third deformation element 213 is realized, and by combining the previous embodiments, the first transmission assembly 22 realizes the linkage of the first deformation element 211 and the second deformation element 212, and the second transmission assembly 23 realizes the linkage of the second deformation element 212 and the third deformation element 213, that is, the first deformation element 211, the second deformation element 212 and the third deformation element 213 can be realized through the movement of the driving assembly 30 and the cooperation of the first transmission assembly 22 and the second transmission assembly 23, and the linkage of a plurality of deformation elements realizes the one-key folding of the body 20 driven by the driving assembly 30, so that the deformation of the deformation toy 1000 is convenient and quick, and the accommodation of the deformation toy 1000 is convenient.

Referring to fig. 17, further, the body 20 further includes a third restoring member 243, and the third restoring member 243 is connected to the second deforming member 212 and the third deforming member 213, respectively, and has an elastic force for driving the third deforming member 213 to fold. When the second transmission assembly 23 moves downwards, the force of the second transmission assembly 23 on the third deformation piece 213 is eliminated, and at the moment, the third deformation piece 213 is urged to be close to the second deformation piece 212 by the elastic force of the third reset piece 243, so that the third deformation piece 213 is folded.

Referring to fig. 12, in some embodiments of the present utility model, the second transmission assembly 23 may include a fourth transmission structure 231, a fifth transmission structure 232 and a sixth transmission structure 233, where the fourth transmission structure 231 is fixed relative to the first deformation member 211, the fifth transmission structure 232 is telescopically disposed on the second deformation member 212 and is in transmission connection with the fourth transmission structure 231, and the sixth transmission structure 233 is rotatably disposed on the second deformation member 212 and is in transmission connection with the fifth transmission structure 232 and the third deformation member 213, respectively. Specifically, the fourth transmission structure 231 may be connected to the first deformation member 211 by a key and fixed on the second deformation member 212, and when the first deformation member 211 rotates, the fourth transmission structure 231 is driven to rotate and simultaneously drive the second deformation member 212 to fold, the fourth transmission structure 231 drives the fifth transmission structure 232 to move downwards, and the fifth transmission structure 232 drives the sixth transmission structure 233 to rotate, so that the folding of the third deformation member 213 is synchronously realized, and thus, the one-key synchronous folding of a plurality of deformation members is realized, and the deformation and storage of the deformation toy 1000 are facilitated.

Referring to fig. 17, further, the fourth transmission structure 231 may have a fourth gear 2311 thereon, one end of the fifth transmission structure 232 may be provided with a second rack 2321 and the other end is provided with a third rack 2322, the sixth transmission structure 233 may have a fifth gear 2331 thereon, wherein the fourth gear 2311 is meshed with the second rack 2321, the third rack 2322 is meshed with the fifth gear 2331, and the fifth gear 2331 is adapted to drive the third deformation element 213 to expand. The fourth transmission structure 231 can be in transmission connection with the first deformation piece 211 and is fixed on the second deformation piece 212, the relative position of the fourth transmission structure 231 is unchanged, when the first deformation piece 211 is folded, the fourth transmission structure 231 can be synchronously driven to rotate and drive the second rack 2321 to move downwards, the second rack 2321 drives the third rack 2322 to move downwards and synchronously drives the fifth gear 2331 to move, and then linkage of a plurality of deformation pieces is achieved, and the transmission structure is high in reliability and stability.

Referring to fig. 18, in some embodiments of the present utility model, the body 20 may further include a fourth deforming member 214, further enriching the shape of the deformed toy 1000, where the fourth deforming member 214 is connected to the sixth transmitting structure 233 and is fixed in relative position. In other words, when the sixth transmission structure 233 rotates, the fourth deforming member 214 can be simultaneously driven to rotate, so as to fold the fourth deforming member 214. The fourth deforming member 214 and the sixth transmission structure 233 may be connected by a key, and the connecting stability and reliability of the fourth deforming member 214 and the sixth transmission structure 233 are improved by the key connection, so as to stably drive the fourth deforming member 214 to fold. In addition, by providing the fourth deforming member 214, the shape of the deformed toy 1000 is enriched, and the interest of the deformed toy 1000 is improved.

According to the deformation toy 1000 of the embodiment of the utility model, the deformation toy 1000 has two forms of an unfolding state and a folding state, wherein the form of the deformation toy 1000 can be a robot, an animal, a vehicle and the like, for example, the unfolding state can be the robot, the animal and the like, the folding state can be a toy car, the interestingness of the deformation toy 1000 can be enriched by switching between different states, and the deformation toy 1000 can be conveniently stored in the folding state. In the following description, taking a folded state as a toy car shape and taking an unfolded state as a robot as an example, in the unfolded state, the transformable toy 1000 may include a first transformable member 211 and a second transformable member 212, the first transformable member 211 may be a leg portion, the second transformable member 212 may be a body, in order to enrich the shape and interest of the transformable toy 1000, the transformable toy 1000 may further include a third transformable member 213 and a fourth transformable member 214, the third transformable member 213 may be an arm portion, and the fourth transformable member 214 may be a wing portion.

In some embodiments of the present utility model, a first rotation axis may be provided between the first deforming member 211 and the base 10, a second rotation axis may be provided between the second deforming member 212 and the first deforming member 211, and a third rotation axis may be provided between the third deforming member 213 and the second deforming member 212, wherein the first rotation axis may be parallel to the second rotation axis and the second rotation axis may be perpendicular to the third rotation axis. For example, the first rotation axis and the second rotation axis may extend along the left-right direction of the toy figure 1000, the third rotation axis may extend along the front-rear direction of the toy figure 1000, after the toy figure 1000 is folded, the first deformation member 211 and the second deformation member 212 may be stacked on the base 10, and the third deformation member 213 may be folded on both sides of the second deformation member 212, so that the toy figure 1000 is compact after being folded, space can be saved, and convenience is brought to storage and carrying of the toy.

In some embodiments of the present utility model, the first deforming member 211 may be folded on the stand 10, and the second deforming member 212 may be folded with the first deforming member 211, so that the configuration of the body 20 is compact when the deforming toy 1000 is switched to the folded state, which can save space and facilitate storage and carrying of the toy.

In some embodiments of the present utility model, the third deforming member 213 may be folded with the second deforming member 212 in the folded state, so that the deformed toy 1000 is compact in structure when being switched to the folded state, which can save space and facilitate storage and carrying of the toy.

In some embodiments of the present utility model, in the unfolded state, the first deformation member 211 may extend in the up-down direction, and the lower end is connected to the base 10, the second deformation member 212 may extend in the up-down direction, and the lower end is connected to the upper end of the first deformation member 211, for example, the unfolded state of the deformation toy 1000 may be a robot, the first deformation member 211 may be a leg, the second deformation member 212 may be a body, the robot is connected to the base 10, so that the overall structure of the robot is stable, a good standing posture can be maintained, and different playing environments can be adapted, and when the unfolded state is switched to the folded state, the first deformation member 211 and the second deformation member 212 can be folded synchronously, so that different forms and shapes can be changed, and the interestingness of the toy can be increased.

In some embodiments of the present utility model, in the unfolded state, the third deforming member 213 may extend in the up-down direction, with an upper end connected to an upper end of the second deforming member 212 and a lower end spaced apart from the second deforming member 212 in the left-right direction. For example, the unfolding state of the deformation member may be a robot, the second deformation member 212 may be a body, the third deformation member 213 may be an arm, one end of the arm is connected to the body and located at two sides of the body, so that the shape of the deformation toy 1000 is enriched, and when the unfolding state is switched to the folding state, the second deformation member 212 and the third deformation member 213 can be synchronously folded, and different shapes and shapes are changed, so that the interest of the toy is increased.

Referring to fig. 19, the toy deformation 1000 may optionally further include an unlocking member 500, and the unlocking member 500 may be separate from the body 20 and the stand 10, or may be disposed to be embedded between the body 20 and the stand 10, and may be adjusted according to the shape of the toy deformation. The seventh transmission structure 16 may include a first transmission portion 161, the stand 10 may further include a magnetic attraction structure 15, the magnetic attraction structure 15 may be connected to the first transmission portion 161, and the magnetic attraction structure 15 is configured to attract the unlocking member 500 and drive the first transmission portion 161 to move to unlock the second locking hook 112. Specifically, the unlocking member 500 may be made of a metal material, and by taking a structure that the unlocking member 500 is separated from the main body portion (the body 20 and the stand 10) of the deformation toy 1000 as an example, the unlocking member 500 may be pushed to move toward the deformation toy 1000, and the deformation toy 1000 may be pushed to move toward the unlocking member 500, when the deformation toy 1000 approaches the unlocking member 500, the unlocking member 500 approaches the magnetic structure 15, the magnetic structure 15 adsorbs the unlocking member 500, and the magnetic structure 15 receives the pushing force of the unlocking member 500 to drive the first transmission portion 161 to move backward and drive the second latch hook 112 to move backward, so as to release the driving member 32.

Referring to fig. 7 to 9, optionally, a roller 171 may be disposed on the stand 10, the seventh transmission structure 16 may include a second transmission portion 162, the stand 10 may further include a cam 172 and a transmission mechanism 173, the cam 172 is connected with the second transmission portion 162 to drive the second transmission portion 162 to move and unlock the second lock hook 112, and the transmission mechanism 173 is respectively connected with the roller 171 and the cam 172 in a transmission manner. Specifically, the roller 171 is rotatably fixed on the stand 10, the roller 171 may be in transmission connection with the transmission mechanism 173, the rotation of the roller 171 may drive the transmission mechanism to transmit, the transmission mechanism drives the cam 172 to rotate, and when the cam 172 rotates to a certain position, the second transmission portion 162 is driven to move backward, and further the second latch hook 112 is driven to move backward, so as to release the driving member 32.

Alternatively, the base 10 may include a first latch hook 111 and a second latch hook 112, where the first latch hook 111 releasably latches the body 20 in the folded state, the second latch hook 112 releasably latches the driving member 32 in the second position, and the second latch hook 112 is synchronously unlocked with the first latch hook 111, in other words, the driving member 32 synchronously moves from the second position to the first position when the body 20 is switched from the folded state to the unfolded state. The first latch hook 111 may be fixed above the seventh transmission structure 16, and when the seventh transmission structure 16 moves, the seventh transmission structure 16 synchronously drives the first latch hook 111 to move, releasing the folded state of the body 20, and ensuring that the second latch hook 112 and the first latch hook 111 are synchronously unlocked.

In combination with the foregoing embodiment, the roller 171 on the base 10 may move, that is, the stroke of the deformation toy 1000 triggers the first latch hook 111 and the second latch hook 112 to unlock synchronously, or may trigger the first latch hook 111 and the second latch hook 112 to unlock synchronously under the action of the unlocking member 500, after the first latch hook 111 and the second latch hook 112 unlock, the driving member 32 is released, and under the action of the elastic force of the fourth reset member 141, the driving member 32 moves to the first position, the body 20 is released synchronously, and the folded state is switched to the unfolded state. By setting a plurality of different forms to trigger the unlocking of the first lock hook 111 and the second lock hook 112, the playing method of the deformation toy 1000 is enriched, and the interestingness of the deformation toy 1000 is improved.

In the following description of the switching process of the transformable toy 1000 from the unfolded state to the folded state of the present utility model with reference to the accompanying drawings, the transformable toy 1000 is in the unfolded state, that is, in the robot state, when the transformable toy 1000 is to be transformed into the toy car shape or the transformable toy 1000 is to be stored for convenience of carrying, the rotatable driving member 32, the second toggle teeth 331 are in driving engagement with the first toggle teeth 131, the fourth rack 13 is driven to move forward, the fourth rack 13 is engaged with the rotating member 31, the rotating member 31 is driven to rotate in the clockwise direction, the rotating member 31 is in driving connection with the first transformable member 211 (leg), the first transformable member 211 (leg) is driven to rotate backward and fold onto the base 10, the first transformable member 211 (leg) drives the first driving structure 221 to move upward during rotation, the upper end of the first rack 2211 is engaged with the first gear 2231, the first gear 2231 is fixedly connected with the second gear 2232 coaxially, the second gear 2232 is meshed with the third gear 2222, the first rack 2211 drives the first gear 2231 and the second gear 2232 to rotate clockwise, the first gear 2231 and the second gear 2232 play a role in reducing speed and increasing torque, and drive the third gear 2222 to rotate counterclockwise, the third transmission structure 222 simultaneously drives the second deformation member 212 (body) to rotate forward and fold on the base 10, because the fourth transmission structure 231 is fixed on the second deformation member 212 (body), the fourth transmission structure 231 does not rotate relative to the second deformation member 212 to drive the second rack 2321 to move downward and drive the third rack 2322 to move downward, the fifth gear 2331 is meshed with the third rack 2322, the third rack 2322 moves downward and drives the fifth gear 2331 to rotate counterclockwise, the sixth transmission structure 233 drives the fourth deformation piece 214 (wings) to rotate and fold in front of the second deformation piece 212 (body) at the same time, meanwhile, the sixth transmission structure 233 drives the folding and two sides of the second deformation piece 212 (body) by the sixth transmission structure 233 under the elastic action of the third reset piece 243 in the rotating process, synchronous linkage folding of all deformation pieces of the body 20 is realized under the driving of the driving assembly 30 through the matching of a plurality of racks and gears, namely, one-key folding of the body 20 is realized under the driving of the driving assembly 30, so that the folding state of the deformation toy 1000 is switched quickly and conveniently, and after folding, the structure arrangement of the deformation toy 1000 is compact, the deformation toy 1000 is changed into a toy car shape, the storage or the carrying of the deformation toy 1000 is facilitated, and the playing experience of a user is improved.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present utility model, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present utility model, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

In the description of the present specification, a description referring to terms "one embodiment," "some embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present utility model. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, the different embodiments or examples described in this specification and the features of the different embodiments or examples may be combined and combined by those skilled in the art without contradiction.

While embodiments of the present utility model have been shown and described above, it will be understood that the above embodiments are illustrative and not to be construed as limiting the utility model, and that variations, modifications, alternatives and variations may be made to the above embodiments by one of ordinary skill in the art within the scope of the utility model.

Claims (15)

1. A transformable toy (1000), comprising:

the device comprises a machine base (10), wherein a driving assembly (30) is arranged on the machine base (10);

a body (20), the body (20) being connected to the housing (10) and having an unfolded state and a folded state;

the drive assembly (30) is in transmission connection with the body (20), the drive assembly (30) being adapted to drive the body (20) to switch from the unfolded state to the folded state.

2. The transformable toy (1000) of claim 1, wherein said driving assembly (30) comprises:

a rotating member (31), wherein the rotating member (31) is in transmission connection with the machine body (20);

-a driving member (32), said driving member (32) being in driving connection with said rotating member (31) and being configured to drive said rotating member (31) and to fold said body (20).

3. The transformable toy (1000) of claim 2, wherein said driving member (32) has a first position and a second position, said driving member (32) is located at said first position when said body (20) is in said unfolded state, said driving member (32) is located at said second position when said body (20) is in said folded state, and said driving member (32) is movable from said first position to said second position to drive said body (20) to switch from said unfolded state to said folded state.

4. The transformable toy (1000) of claim 1, wherein said body (20) comprises:

the first deformation piece (211), the first deformation piece (211) is rotatably connected with the base (10) and is in transmission connection with the driving component (30);

a second deforming member (212), the second deforming member (212) being rotatably connected to the first deforming member (211);

the first transmission assembly (22), first transmission assembly (22) respectively with frame (10), first deformation piece (211) with second deformation piece (212) link to each other for first deformation piece (211) with second deformation piece (212) linkage is in order to fold in step.

5. The transformable toy (1000) of claim 4, wherein said body (20) further comprises:

a first restoring member (241), wherein the first restoring member (241) is connected to the stand (10) and the first deforming member (211) respectively, and has an elastic force for driving the first deforming member (211) to expand; and/or

And the second reset piece (242) is respectively connected with the first deformation piece (211) and the second deformation piece (212), and has elastic force for driving the second deformation piece (212) to be unfolded.

6. The toy deformation (1000) according to claim 5, wherein the housing (10) has a first latch hook (111), the first latch hook (111) releasably locking the body (20) in the folded state,

Wherein the first deformation member (211) and the second deformation member (212) are folded on the base (10) when the body (20) is in the folded state, and are locked by the first lock hook (111).

7. The transformable toy (1000) of claim 4, wherein said first transmission assembly (22) comprises:

the first transmission structure (221), the first transmission structure (221) is telescopically arranged on the first deformation piece (211), one end of the first transmission structure is in sliding connection with the base (10), and the first deformation piece (211) is suitable for driving the first transmission structure (221) to stretch when rotating;

and the second transmission structure (222) is rotatably arranged on the first deformation piece (211) and is respectively in transmission connection with the first transmission structure (221) and the second deformation piece (212).

8. The transformable toy (1000) of claim 7, wherein said first transmission assembly (22) further comprises:

a third transmission structure (223), wherein the third transmission structure (223) is rotatably arranged on the first deformation piece (211), the third transmission structure (223) comprises a first gear (2231) and a second gear (2232) which are coaxial and fixedly connected,

the first transmission structure (221) is provided with a first rack (2211), the second transmission structure (222) is provided with a third gear (2222), the first rack (2211) is meshed with the first gear (2231), the third gear (2222) is meshed with the second gear (2232), and the number of teeth of the third gear (2222) is smaller than that of the second gear (2232).

9. The transformable toy (1000) according to claim 7, wherein said base (10) is provided with a chute (12), an end portion of said first transmission structure (221) being slidably engaged with said chute (12), said chute (12) extending from one end to the other around a rotation center of said second transmission structure (222) and gradually away from the rotation center of said second transmission structure (222).

10. The transformable toy (1000) of claim 4, wherein said body (20) further comprises:

a third deformation element (213), the third deformation element (213) being rotatably connected to the second deformation element (212);

the second transmission assembly (23), second transmission assembly (23) respectively with second deformation piece (212) with third deformation piece (213) is used for third deformation piece (213) with second deformation piece (212) linkage is in order to fold in step.

11. The transformable toy (1000) of claim 10, wherein said body (20) further comprises:

and a third restoring member (243), wherein the third restoring member (243) is connected to the second deforming member (212) and the third deforming member (213), respectively, and has an elastic force for driving the third deforming member (213) to fold.

12. The transformable toy (1000) of claim 10, wherein said second transmission assembly (23) comprises:

a fourth transmission structure (231), wherein the fourth transmission structure (231) and the first deformation piece (211) are fixed in relative positions;

a fifth transmission structure (232), wherein the fifth transmission structure (232) is telescopically arranged on the second deformation piece (212) and is in transmission connection with the fourth transmission structure (231);

and the sixth transmission structure (233) is rotatably arranged on the second deformation piece (212) and is respectively in transmission connection with the fifth transmission structure (232) and the third deformation piece (213).

13. The transformable toy (1000) according to claim 12, wherein said fourth transmission structure (231) is provided with a fourth gear (2311), one end of said fifth transmission structure (232) is provided with a second rack (2321) and the other end is provided with a third rack (2322), said sixth transmission structure (233) is provided with a fifth gear (2331), wherein said fourth gear (2311) is meshed with said second rack (2321), said third rack (2322) is meshed with said fifth gear (2331), and said fifth gear (2331) is adapted to drive said third transformable element (213) to expand.

14. The transformable toy (1000) of claim 12, wherein said body (20) further comprises:

and the fourth deformation piece (214), wherein the fourth deformation piece (214) is connected with the sixth transmission structure (233) and has a fixed relative position.

15. The transformable toy (1000) according to claim 10, wherein a first rotation axis is provided between said first transformable member (211) and said base (10), a second rotation axis is provided between said second transformable member (212) and said first transformable member (211), a third rotation axis is provided between said third transformable member (213) and said second transformable member (212), said first rotation axis is parallel to said second rotation axis, and said second rotation axis is perpendicular to said third rotation axis;

and/or, in the folded state, the first deforming member (211) is folded on the stand (10), and the second deforming member (212) is folded with the first deforming member (211);

and/or, in the folded state, the third deformation (213) is folded with the second deformation (212);

and/or, in the unfolded state, the first deformation piece (211) extends along the up-down direction, the lower end of the first deformation piece is connected with the base (10), the second deformation piece (212) extends along the up-down direction, and the lower end of the second deformation piece is connected with the upper end of the first deformation piece (211);

And/or, in the unfolded state, the third deformation member (213) extends in the up-down direction, the upper end is connected with the upper end of the second deformation member (212), and the lower end is spaced apart from the second deformation member (212) in the left-right direction.