CN111744215A - Deformation toy - Google Patents

Abstract

The invention belongs to the field of toys, and discloses a deformation toy which is a combined toy capable of multi-stage deformation and comprises a first toy and a second toy, wherein the first toy and the second toy are provided with an initial first form and a final second form; the second toy in the first form can be locked on the first toy in the first form, and the transformable toy is in an initial combination state; the deformed toy is stored energy and moves forwards, in the process of moving forwards, the second toy is separated from the first toy forwards, and the deformed toy is in a middle separation state; the first toy moves forward to collide with the second toy, both of which change into the second shape, and the first toy and the second toy separate or combine, and the deformed toy is in the last separated or combined deformed state. The deformation toy can realize multi-stage and diversified deformation and is high in interestingness.

Description

Deformation toy

Technical Field

The invention relates to the field of toys, in particular to a deformation toy.

Background

The transformable toy is generally composed of one or two transformable bodies. In the case of a transformable toy composed of two transformable bodies, the two separate transformable bodies may be united and transformed, or the two united transformable bodies may be separated and transformed. Generally speaking, the transformation toy has single type, simple transformation action and poor interest, and is difficult to meet the requirements of children players.

Disclosure of Invention

The invention aims to provide a deformation toy which can realize multi-stage deformation and is high in interestingness.

In order to realize the purpose, the following technical scheme is provided:

a transformable toy which is a composite toy capable of multi-stage transformation, comprising a first toy and a second toy, each of the first toy and the second toy having an initial first configuration and a final second configuration;

said second toy of the first configuration being lockable to said first toy of the first configuration, said transformable toy being in an initial assembled state;

the transformable toy is stored with energy and moves forwards, in the process of moving forwards, the second toy is separated from the first toy forwards, and the transformable toy is in a middle separation state;

the first toy moves forward to collide with the second toy, both of which are changed into a second configuration, and the first toy and the second toy are separated or integrated, the transformable toy being in a final separated or integrated transformed state.

Furthermore, a first triggering deformation assembly, a locking assembly and an energy storage assembly are arranged on the first toy, the first toy moves backwards to store energy for the energy storage assembly in a first state, the energy storage assembly is connected with the locking assembly, the first toy moves forwards under the driving of the energy storage assembly after the energy storage is finished, the energy storage assembly drives the locking assembly to unlock in the forward moving process, the first triggering deformation assembly is pressed by external force, and the first toy changes into a second state;

the second toy in the first form is locked on the first toy in the first form through the locking assembly so that the transformable toy is in an initial state, when the locking assembly is unlocked, the second toy is forwards separated from the first toy so that the transformable toy is in a separated state, and a second triggering transformation assembly is arranged on the second toy;

when the first toy moves forwards to collide with the second toy, the first triggering deformation assembly and the second triggering deformation assembly are triggered by the second toy and the first toy respectively, the first triggering deformation assembly and the second triggering deformation assembly are changed into a second form, and the deformation toy is in a deformation state.

Furthermore, the front end of the first toy is provided with a first magnetic attraction structure, the second toy is internally provided with a second magnetic attraction structure, the first toy moves forwards to collide with the second toy and deform, and the first magnetic attraction structure and the second magnetic attraction structure attract each other.

Furthermore, the first toy is further provided with a first rotating part, the non-end part of the first rotating part is pivoted with the first toy through a torsion spring, the locking assembly comprises a limiting lug which is arranged at the front end of the first rotating part and protrudes out of the upper end of the first toy, the locking assembly further comprises a limiting notch which is arranged at the rear end of the first rotating part and a first elastic trigger structure which can be matched with or separated from the limiting notch, so that the locking assembly is locked or unlocked.

Furthermore, the first elastic trigger structure comprises a first trigger structure and a first elastic element, one end of the first trigger structure is connected with the first elastic element, the other end of the first trigger structure can be matched with or separated from the limit notch, and the first trigger structure can be meshed with or separated from the output end of the energy storage assembly;

when the locking assembly is separated, the first trigger structure is matched with the limiting notch under the action of the first elastic element, and the locking assembly is locked;

when the first toy is meshed with the second toy, the first trigger structure is separated from the limiting notch, the first rotating piece rotates forwards relative to the first toy under the action of the torsion spring, the locking assembly is unlocked, and the second toy is pushed forwards away from the first toy by the first rotating piece.

Furthermore, the energy storage assembly comprises a return gear box and a transmission structure, the transmission structure comprises a driving gear, an intermediate gear, a ratchet and a driven gear, the driving gear is coaxially and fixedly connected with an output shaft of the return gear box, the intermediate gear is provided with external teeth meshed with the driving gear and internal teeth matched with the ratchet, the driven gear is coaxially and fixedly connected with the ratchet, part of the driven gear is circumferentially provided with a first tooth structure, the first trigger structure is arranged on one side of the driven gear, and a second tooth structure capable of being meshed with the first tooth structure is arranged on the first trigger structure;

when the ratchet wheel is static, the first tooth structure is separated from the second tooth structure, and the first trigger structure is matched with the limiting notch;

when the ratchet wheel rotates along with the intermediate gear, the first tooth structure can be meshed with the second tooth structure, and the first trigger structure is separated from the limiting notch.

Furthermore, the energy storage assembly further comprises a first rear wheel which is connected with the first toy in a rotating mode, the first rear wheel is coaxially and fixedly connected with an output shaft of the return gear box and moves backwards to the first toy, and the first rear wheel rotates and stores energy to the return gear box through the output shaft.

Furthermore, the first toy comprises a first shell, the first triggering deformation component is connected with the first shell, and the first magnetic attraction structure is arranged at the front end of the first shell.

Further, the first trigger deforming assembly includes:

the two second rotating pieces are respectively arranged at the left side and the right side of the first shell and are pivoted with the first shell;

the two third rotating parts are respectively arranged at the left side and the right side of the first shell and are pivoted with the first shell, and the third rotating parts are positioned at the rear sides of the second rotating parts;

the second elastic trigger structure is movably arranged in the first shell and extends out of the front end of the first shell;

the first locking part is arranged in the first shell and matched with the second elastic trigger structure, so that the first locking part can be stretched or folded along the left-right direction of the first shell;

the second locking part is arranged in the first shell and matched with the second elastic trigger structure, so that the second locking part can be stretched or folded along the left-right direction of the first shell;

when the second elastic triggering structure is not triggered, the first locking part extends, two ends of the first locking part respectively extend from the left side and the right side of the first shell and are matched with the second rotating part to lock the second rotating part, and two ends of the second locking part extend from the left side and the right side of the first shell and are matched with the third rotating part to lock the third rotating part;

when the second elastic trigger structure is triggered, the first locking part is folded, two ends of the first locking part are separated from the second rotating part respectively, the second rotating part is unlocked and rotates, the second locking part is folded, two ends of the second locking part are separated from the third rotating part respectively, and the third rotating part is unlocked and rotates.

Furthermore, the left side and the right side of the first shell are both provided with first guide grooves, the second rotating part is provided with a first sliding end, the first sliding end can slidably penetrate through the first guide grooves and is connected with the inner wall of the first shell through a fifth elastic element, and after the second rotating part is unlocked, the second rotating part slides along the first guide grooves under the action of the fifth elastic element;

the left and right sides of first casing still all is equipped with the second guide way, the third rotates and is equipped with the second sliding end, second sliding end slidable ground passes the second guide way, the second rotate the piece with be connected with the torsional spring between the first casing, by the unblock back, the second rotates the piece and is in follow under the effect of torsional spring the second guide way slides.

Further, when the first toy moves forward to collide with the second toy, the front end part of the second elastic trigger structure extending out of the first shell is pressed by the second toy, and the first trigger deformation component is triggered.

Further, the second toy includes the second casing, the second triggers the deformation subassembly including all with two fourth rotation pieces and two fifth rotation pieces of second casing pin joint, two the fifth rotation piece is located the rear end of second casing, the fifth rotation piece still includes the third trigger structure, the third triggers the structure movably to be located the fifth rotation piece is followed the rear end of fifth rotation piece is stretched out, the fourth rotation piece can with the front end cooperation of third trigger structure and with the lock joint of fifth rotation piece is in order to lock the fifth rotation piece triggers the third triggers the structure, the fourth rotation piece rotates and with the separation of fifth rotation piece, two the fifth rotation piece is unlocked, and respectively for the second casing rotates to the left and right sides.

Further, the second triggers subassembly that warp still includes the sixth rotation piece, the sixth rotation piece is also located the rear end of second casing and with the second casing pin joint, the sixth rotation piece is located two the centre of fifth rotation piece, the fifth rotation piece can with the cooperation of sixth rotation piece to locking sixth rotation piece, when the fifth rotation piece was unlocked and rotated, the fifth rotation piece with the separation of sixth rotation piece, the sixth rotation piece is unlocked, and for the second casing upwards rotates.

Further, when the first toy moves forward to collide with the second toy, the part of the third trigger structure extending out of the rear end of the fifth rotating piece is pressed by the first toy, and the second trigger deformation component is triggered.

Furthermore, the second magnetic attraction structure is arranged at the rear end of the second shell, the first toy is moved forwards to collide with the second toy, the second triggering deformation component is triggered, and the first magnetic attraction structure and the second magnetic attraction structure are attracted.

Furthermore, the second triggering deformation assembly further comprises a fourth elastic triggering structure and a protruding portion, the fourth elastic triggering structure is movably arranged in the second shell and extends out of the rear end of the second shell, the protruding portion is also arranged in the second shell and extends out of the front end of the second shell, and the protruding portion is matched with the fourth elastic triggering structure and can move together with the fourth triggering structure so as to extend forwards or retract backwards relative to the front end of the second shell.

Further, when the first magnetic attraction structure and the second magnetic attraction structure are attracted, the first toy triggers the fourth elastic trigger structure, the protruding portion moves forwards along with the fourth trigger structure, and the protruding portion extends forwards relative to the front end of the second shell.

Compared with the prior art, the deformation toy provided by the invention has the following beneficial effects:

the transformable toy includes a first toy and a second toy. The first toy and the second toy each have a first configuration and a second configuration. First, the first toy and the second toy in the first form can be combined (integrated) by the locking member to form the transformable toy in the first form. After the energy storage assembly unlocks the locking assembly, the first toy and the second toy are separated (one in two). Then, the first toy catches up with the second toy under the driving of the energy storage assembly, the first toy and the second toy collide, the first triggering deformation assembly and the second triggering deformation assembly are mutually triggered, and both the first triggering deformation assembly and the second triggering deformation assembly deform. The two toys are different in shape before combination and after separation.

Furthermore, the rear end of the first toy is provided with a first magnetic attraction structure, the second toy is also provided with a second magnetic attraction structure, and the second magnetic attraction structure and the first magnetic attraction structure can attract each other in the collision deformation process of the first toy and the second toy, so that the first toy and the second toy are combined (two combined). The invention can realize the deformation actions of two-in-one, one-in-two and two-in-one at last, and has strong interestingness.

Drawings

FIG. 1 is a schematic structural view of a first toy according to an embodiment of the present invention in a first configuration;

FIG. 2 is a schematic structural view of a second toy according to an embodiment of the present invention in a first configuration;

FIG. 3 is a schematic structural diagram of a first configuration of a transformable toy according to an embodiment of the present invention;

FIG. 4 is a schematic structural view of a first toy according to an embodiment of the present invention in a second configuration;

figure 5 sets forth a first isometric view of a second toy according to embodiments of the present invention in a second configuration;

FIG. 6 is a second isometric view of a second toy according to embodiments of the present invention in a second configuration;

FIG. 7 is a first schematic structural view of a transformable toy according to a second configuration provided by an embodiment of the present invention;

FIG. 8 is an enlarged view of a portion of FIG. 1 at A;

FIG. 9 is a schematic view of the connection between the transmission shaft, the transmission structure and the third rotating member according to the embodiment of the present invention; (ii) a

FIG. 10 is a semi-sectional view of a transformable toy according to an embodiment of the present invention in a first configuration;

FIG. 11 is an enlarged view of a portion of FIG. 10 at B;

FIG. 12 is a first exploded view of a second toy according to an embodiment of the present invention in a first configuration;

FIG. 13 is a second exploded perspective view of a second toy according to the first aspect of the present invention (with the top cover and the sixth rotatable member hidden);

FIG. 14 is a schematic structural view of a first toy (hidden first shell) in a first configuration according to an embodiment of the present invention;

fig. 15 is a schematic view of an inner side structure of the first housing according to the embodiment of the present invention;

fig. 16 is an outer side structural schematic view of the first housing according to the embodiment of the present invention;

FIG. 17 is a schematic view of the second rotating member, the third rotating member and the positioning member in a first configuration of the first toy of the present invention;

FIG. 18 is a schematic view of the second rotating member, the third rotating member and the positioning member assembled with the first housing when the first toy is in the first configuration according to the present invention;

FIG. 19 is a schematic view of the second rotating member, the third rotating member and the positioning member assembled with the first housing when the first toy is in the second configuration according to the present invention;

FIG. 20 is a schematic view of the assembly of the shaped member and the first housing in the second configuration of the first toy of the present invention;

fig. 21 is a second schematic structural view of a transformable toy according to a second embodiment of the present invention.

Reference numerals:

deformation toy 3000

First toy 1000

A first housing 1 a; the accommodation site 11 a; a first through hole 12 a; a first plugging site 121 a; a third through hole 13 a; a fourth through hole 14 a; the first guide groove 15 a; the second guide groove 16 a; a slide connector 17 a; a bounding box 18 a; a recess 19 a;

a first triggering structure 2 a;

the first rotating member 3 a; a limit notch 31 a;

a second rotating member 4 a; the first sliding end 41 a; a stopper portion 42 a;

a third rotating member 5 a; the second sliding end 51 a; a second plug site 45 a;

a shaped piece 6 a; the third guide groove 61 a;

a second triggering structure 7 a; the guide posts 71 a;

an insert plate 8 a;

the first rear wheel 91 a; a first front wheel 92 a; a drive shaft 93 a;

the transmission case 94 a; a drive gear 95 a; the intermediate gear 96 a; a ratchet 97 a; the driven gear 98 a;

a return force gear box 60;

a first elastic element 10; a fifth elastic element 50; a third elastic element 30; a fourth elastic element 40; a first magnetic attraction structure 100;

second toy 2000

A second housing 1 b; an upper cover 11 b; a bottom plate 12 b;

a fourth rotating member 2 b; a fastening portion 21 b;

a fifth rotating member 3 b; a body portion 31 b; side plates 311 b; a first socket portion 3111 b;

a third trigger structure 32 b; third trigger structure

A sixth rotating member 4 b;

a fourth trigger structure 5 b; a card slot 51 b;

the protruding portion 6 b;

the second rear wheel 71 b; a second front wheel 72 b;

a second magnetic attraction structure 200;

a second elastic element 20.

Detailed Description

In order to make the technical problems solved, technical solutions adopted and technical effects achieved by the present invention clearer, the technical solutions of the embodiments of the present invention will be described in further detail below with reference to the accompanying drawings, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, which refer to orientations or positional relationships based on those shown in the drawings, are used only for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the referred device or element must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the present invention.

As shown in fig. 1-7, the present embodiment provides a transformable toy 3000. The transformable toy 3000 may optionally include a first toy 1000 and a second toy 2000. The first toy 1000, the second toy 2000, and the transformable toy 3000 each have a first configuration in which they are collapsed and a second configuration in which they are expanded.

Preferably, the first configuration of the first toy 1000, the second toy 2000, and the transformable toy 3000 are all vehicle configurations (see fig. 1 and 2), and the second configuration of the first toy 1000, the second toy 2000, and the transformable toy 3000 are all animal configurations (see fig. 4-6). The present embodiment will be explained by taking as an example that the first form of the first toy 1000, the second toy 2000, and the transformable toy 3000 are all vehicle forms, and the second form of the first toy 1000, the second toy 2000, and the transformable toy 3000 is an animal form. In other embodiments, the shape of the associated structures on first toy 1000 and second toy 2000 may be modified without changing the coupling and gearing relationships to provide first toy 1000 and/or second toy 2000 with, for example, an animated character, flower, or other configuration.

The first toy 1000 may optionally include a first triggered deforming assembly, a locking assembly, and an energy storage assembly. The second toy 2000 may optionally include a second triggered morphing assembly.

In this embodiment, the play process of the transformable toy 3000 is substantially as follows:

in the first configuration, the first toy 1000 may have the second toy 2000 locked thereto via the locking assembly, resulting in a transformable toy 3000 in the first configuration (see fig. 3).

Thereafter, pulling the first toy 1000 backwards may charge the energy storage assembly. When the first toy 1000 is released and the energy storage is finished, the energy storage assembly drives the first toy 1000 and the second toy 2000 thereon to move forwards together. During forward movement, the energy storage assembly will unlock the locking assembly and the second toy 2000 will disengage the first toy 1000 forward.

Then, the first toy 1000 can catch up and strike the second toy 2000 under the driving of the energy storage assembly, when striking, the first toy 1000 triggers the second triggering deformation assembly on the second toy 2000, the second toy 2000 triggers the first triggering deformation assembly on the first toy 1000, and both the first toy 1000 and the second toy 2000 are deformed and converted into the second shape. This makes the first toy 1000 and the second toy 2000 different in form from each other before and after the combination.

Optionally, the front end of the first toy 1000 is provided with a first magnetic attraction structure 100 (see fig. 14), and the front end of the second toy 2000 is provided with a second magnetic attraction structure 200 (see fig. 13). The first magnetic attraction structure 100 and the second magnetic attraction structure 200 can magnetically attract each other. The first magnetic attraction structure 100 and the second magnetic attraction structure 200 are made of magnetic materials or materials capable of generating magnetic attraction force with the magnetic materials. In the process of striking and deforming, the first magnetic attraction structure 100 and the second magnetic attraction structure 200 attract each other magnetically, and finally the combined body of the first toy 1000 and the second toy 2000 in the second form, i.e. the deformation toy 3000 in the second form, is obtained.

The first trigger deforming assembly may optionally include a second resilient trigger structure. The second elastic trigger structure may selectively include a second trigger structure 7a and a third elastic element 30 (see fig. 14). The second trigger structure 7a is movably disposed within the first toy 1000 and extends from the front end of the first toy 1000.

The second trigger deforming assembly may optionally include a third trigger structure 32b (see fig. 12) and a fourth resilient trigger structure. A third trigger structure 32b is movably disposed within the second toy 2000 and extends from a rear end of the second toy 2000. The fourth elastic trigger structure includes a fourth trigger structure 5b (see fig. 6) and a second elastic element 20. In the first configuration, the fourth trigger structure 5b is located inside the second toy 2000, and the fourth trigger structure 5b is movable within the second toy 2000.

Based on the play process, the structure of the transformable toy 3000 is explained as follows:

specifically, referring to fig. 1 and 4, the first toy 1000 may further optionally include a first housing 1a and a first rotating member 3 a. The first housing 1a mainly serves as a support for the vehicle body or animal body. The first rotating member 3a is located at the rear end of the first casing 1a, and is shaped like a tail of an animal, which may be a tail of a vehicle or a tail of an animal. The upper end of the first rotating member 3a is pivotally connected to the first casing 1a, and a torsion spring is disposed between the first rotating member and the first casing. The top of the first casing 1a is provided with a first through hole 12a, and the upper front end of the first rotating member 3a extends out of the first casing 1a through the first through hole 12a, and forms a first inserting position 121a together with the first through hole 12a (see fig. 8).

The locking assembly includes the first plug site 121 a. The rear end of the second toy 2000 is provided with a first socket 3111b matched with the first socket 121 a. The second toy 2000 in the first form is placed above the first housing 1a of the first toy 1000 in the first form, and the first socket portion 3111b is inserted into the first socket 121a (see fig. 10), so that the second toy 2000 is locked, whereby the second toy is united, and the transformable toy 3000 in the first form is obtained.

Further, the locking assembly further comprises a first elastic triggering structure capable of locking and structuring the first rotating member 3 a. The first elastic trigger structure includes a first trigger structure 2a (see fig. 10 and 11) and a first elastic element 10. The first elastic element 10 is preferably a spring. The first rotating member 3a is provided with a limiting notch 31a, the first trigger member is inserted into the limiting notch 31a to lock the first rotating member 3a, and the torsion spring connected between the first rotating member 3a and the first housing 1a is in an energy storage state. The first triggering structure 2a can be separated from the first rotating member 3a by the energy storage assembly to unlock the first rotating member (see fig. 11 analysis below).

Referring to fig. 1 and 4, the first trigger deforming assembly may further optionally include: the second rotating member 4a and the third rotating member 5a, which are disposed on both sides of the first housing 1a and the first rotating member 3a, may be used as wings or limbs of animals. The second rotating member 4a on both sides of the first casing 1a, the first rotating member 3a at the rear end of the first casing 1a, and the first casing 1a together form a receiving position 11a for receiving the second toy 2000, and the second rotating member 4a further defines the second toy 2000 to prevent the second toy 2000 from being separated from the first toy 1000. Both the second rotating member 4a and the third rotating member 5a are rotatable on the side surface of the first housing 1a with respect to the first housing 1a (see the following description).

Further, referring to fig. 1 and 9, the first toy 1000 may further optionally include two first front wheels 92a and two first rear wheels 91 a. The two first front wheels 92a are rotatably connected to the second rotating member 4a, respectively. The inner side of the rear part of the first casing 1a is provided with a transmission shaft 93a, and two ends of the transmission shaft 93a are fixedly connected with the first rear wheel 91a after sequentially passing through the first casing 1a and the third rotating part 5 a. The transmission shaft 93a is rotatably connected to both the first casing 1a and the third rotating member 5 a. The third rotating member 5a and the first housing 1a are connected by a transmission shaft 93a and a first rear wheel 91 a. The two first rear wheels 91a are driving wheels, and both of them and the transmission shaft 93a are part of the energy storage assembly. The two first front wheels 92a are driven wheels.

Referring to fig. 9 and 11, the energy storage assembly further comprises: a return gearbox 60 and a transmission structure arranged on a transmission shaft 93a in the first shell 1 a. The transmission shaft 93a serves as an output shaft of the return gearbox 60 and is driven to rotate by the return gearbox 60. The transmission structure includes a transmission case 94a and a gear train provided in the transmission case 94 a. The transmission case 94a is fixedly connected to the inner wall of the first housing 1 a. The gear train may optionally include a drive gear 95a, an intermediate gear 96a, a ratchet gear 97a, and a driven gear 98 a. The driving gear 95a is fixed to the transmission shaft 93a and engaged with the intermediate gear 96 a. The intermediate gear 96a is provided with external teeth and internal teeth, which are engaged with the drive gear 95a by the external teeth and engaged with the ratchet 97a by the internal teeth. The ratchet 97a is coaxially and fixedly connected with the driven gear 98 a. A portion of the driven gear 98a is circumferentially provided with a first tooth structure.

Referring to fig. 11, the first triggering mechanism 2a is disposed in the transmission case 94a and on one side of the driven gear 98a, and is provided with a second tooth structure capable of meshing with the first tooth structure of the driven gear 98 a. The first triggering structure 2a has one end connected to the transmission case 94a through the first elastic element 10, and the other end extending out of the transmission case 94a and engaging with the first rotating member 3a to lock the first rotating member 3 a. The first elastic element 10 is mainly used for resetting the first triggering structure 2 a.

After the first form of the first toy 1000 and the first form of the second toy 2000 are combined into the first form of the transformable toy 3000, the transformable toy 3000 is pulled to move backwards, the first rear wheel 91a of the first toy 1000 rotates clockwise under the action of friction force, the transmission shaft 93a and the driving gear 95a rotate clockwise under the driving of the first rear wheel 91a, the transmission shaft 93a stores energy to the return gear box 60, the intermediate gear 96a rotates counterclockwise under the driving of the driving gear 95a, and at this time, due to the existence of the ratchet 97a, the driven gear 98a and the ratchet 97a are kept fixed and cannot rotate together. The transformable toy 3000 is released, at the moment of releasing, the first rear wheel 91a loses the power of clockwise rotation, but at the same time, the transmission shaft 93a serving as the output shaft of the return gearbox 60 rotates in the opposite direction (i.e., counterclockwise) under the action of the return gearbox 60, the driving gear 95a and the first rear wheel 91a rotate counterclockwise under the driving of the transmission shaft 93a, at the moment, the first rear wheel 91a serves as a driving wheel to drive the first toy 1000 to move forward, at the same time, the intermediate gear 96a rotates clockwise under the driving of the driving gear 95a, and at the moment, due to the existence of the ratchet 97a, the driven gear 98a and the ratchet 97a rotate clockwise along with the intermediate gear 96 a.

After the driven gear 98a rotates clockwise for a certain angle, the first tooth structure on the driven gear contacts and engages with the second tooth structure on the first triggering structure 2a, the driven gear 98a drives the first triggering structure 2a to move in a direction departing from the first rotating member 3a, and the first triggering structure 2a is separated from the first rotating member 3a to unlock the first rotating member 3 a. After the first rotating member 3a is unlocked, it rotates upward relative to the first casing 1a under the action of the torsion spring (see fig. 4), the first toy 1000 deforms for the first time, and simultaneously the first rotating member 3a pushes the second toy 2000 forward in the rotating process, and the front end of the first rotating member 3a extending out of the first casing 1a moves toward the inside of the first casing 1a, the first inserting part 3111b is separated from the first inserting position 121a, the locking assembly is unlocked, and the second toy 2000 is pushed away from the first toy 1000 forward.

Alternatively, the upper portion of the first casing 1a is continuously inclined downward from the front to the rear to facilitate the downward sliding of the second toy 2000.

After the second toy 2000 is separated from the first toy 1000, it continues to move forward under the thrust of the first rotating member 3a and its own inertia. The first toy 1000, although being subjected to the reaction force of the second toy 2000 in the backward direction, continues to move forward by the return force gearbox 60, and the speed of the first toy 1000 catches up and exceeds the speed of the second toy 2000 due to the return force gearbox 60. After the first toy 1000 catches up with the second toy 2000, it will collide and trigger the third trigger structure 32b extending from the rear end of the second toy 2000.

It should be noted that, when the first rotating member 3a pushes the second toy 2000, the acting force of the first rotating member and the second rotating member is small, the third triggering structure 32b at the rear end of the second toy 2000 is not triggered, and the third triggering structure 32b is triggered only when the first toy 1000 catches up again and hits the second toy 2000.

It should be noted that, since the first tooth structure is only partially circumferentially disposed on the driven gear 98a, during the forward movement of the first toy 1000 under the action of the return gearbox 60, the driven gear 98a continues to rotate clockwise and is separated from the first trigger structure 2a, and the first trigger structure 2a is reset under the action of the first elastic element 10.

Referring to fig. 12 and 13, the second toy 2000 may optionally include a second housing 1b, and the second triggering transformation assembly may optionally further include two fourth rotating members 2b, two fifth rotating members 3b, and a sixth rotating member 4b pivotally coupled to the second housing 1 b. The second shell 1b mainly plays a supporting role and can be used as a vehicle head or an animal head. The two fourth rotating members 2b are movably disposed in the two second housings 1b, respectively. The fifth rotating member 3b and the sixth rotating member 4b are located at the rear end of the second housing 1b, and the two fifth rotating members 3b are respectively disposed at both sides of the sixth rotating member 4 b.

Alternatively, referring to fig. 2, the second toy 2000 further includes a second front wheel 72b rotatably coupled to the second casing 1b, and a second rear wheel 71b rotatably coupled to the fifth rotating member 3b to ensure smooth forward movement of the second toy 2000 after being separated from the first toy 1000.

Referring to fig. 12, the second casing 1b specifically includes a bottom plate 12b and an upper cover 11 b. The two fourth rotating members 2b are pivotally connected to the bottom plate 12b, and connected to the upper cover 11b via torsion springs, and can rotate on the bottom plate 12b relative to the bottom plate 12 b. The fourth rotating member 2b is further provided with a locking portion 21b facing the rear end.

The upper part of the fifth rotating member 3b is pivotally connected to the upper cover 11b and connected to a torsion spring. The fifth rotating member 3b may optionally include a hollow main body portion 31b and the third triggering structure 32 b. The third trigger structure 32b is movably disposed in the main body 31b and extends from a rear end of the main body 31 b. The third triggering structure 32b is provided with a sliding groove (not shown in the figure) at a portion inside the main body 31b, and the main body 31b is provided with a limiting column (not shown in the figure) matched with the sliding groove, wherein the limiting column guides and limits the third triggering structure 32 b. A portion of the main body 31b near the fourth rotor 2b is provided with a second through hole (not shown) penetrating in the thickness direction. The buckling part 21b of the fourth rotating member 2b extends into the main body 31b through the second through hole under the action of the torsion spring, and abuts against the front end of the third triggering structure 32 b. The fourth rotor 2b cooperates with the stopper to lock the third trigger structure 32b in the body 31 b. Meanwhile, the latch 21b of the fourth rotating member 2b is also abutted against the inner wall of the side plate 311b of the main body 31b, so that the fifth rotating member 3b is locked, and at this time, the torsion spring connected between the fifth rotating member 3b and the second housing 1b is in a stored energy state. The rear end of the side plate 311b protrudes downward to form the first mating portion 3111b (see fig. 10).

The left and right sides of the sixth rotating member 4b are provided with clamping portions. A clamping position (not shown in the figure) matched with the clamping position is arranged on one side, close to the sixth rotating part 4b, of the main body part 31b of the fifth rotating part 3b so as to lock the sixth rotating part 4b, and at the moment, the torsion spring connected between the sixth rotating part 4b and the second shell 1b is in an energy storage state.

When the first toy 1000 catches up and strikes the third trigger structure 32b protruding from the rear end of the second toy 2000, the third trigger structure 32b receives a forward striking force and moves forward relative to the body portion 31 b. The third triggering structure 32b pushes the latch 21b of the fourth rotating member 2b, so that the fourth rotating member 2b rotates outwardly on the bottom plate 12b and is separated from the main body 31b to unlock the fifth rotating member 3 b. The fifth rotating pieces 3b are unlocked, the two fifth rotating pieces 3b rotate outwards relative to the second shell 1b under the action of the torsion spring, and meanwhile, the clamping parts on the fifth rotating pieces 3b are separated from the clamping positions on the sixth rotating pieces 4b, so that the sixth rotating pieces 4b are unlocked. After the sixth rotating member 4b is unlocked, the sixth rotating member 4b is rotated upward with respect to the upper cover 11b by the torsion spring. At this point, the second toy 2000 completes the first transformation.

After the third triggering structure 32b is triggered, the two fifth rotating parts 3b are unlocked firstly, and the sixth rotating part 4b is unlocked after the fifth rotating parts 3b rotate for a certain distance, so that the whole action is smooth and layered, the playing method is novel, and the interestingness is strong.

It should be noted that, when the fourth rotating member 2b is separated from the main body portion 31b and the third triggering structure 32b of the fifth rotating member 3b, it is reset by the torsion spring.

The second toy 2000 is transformed for the first time, and the fifth rotating member 3b and the sixth rotating member 4b, which are located at the rear end of the second casing 1b, are rotated above and at both sides of the second casing 1b, respectively, so that the rear end of the second casing 1b is transformed into the rear end of the second toy 2000 (see fig. 6). The second magnetic attraction structure 200 is disposed at the rear end of the second casing 1b (see fig. 13), and the fourth triggering structure 5b extends from the rear end of the second casing 1 b. The first toy 1000 continues to chase forward and the second toy 2000 under the action of the return force gearbox 60. When the distance between the first magnetic attraction structure 100 and the second magnetic attraction structure 200 reaches a certain distance, the first magnetic attraction structure 100 at the front end of the first toy 1000 and the second magnetic attraction structure 200 at the rear end of the second toy 2000 are magnetically attracted to each other, and the first toy 1000 and the second toy 2000 are combined. At the same time, the fourth triggering structure 5b collides with the second triggering structure 7a and triggers each other, and both the first toy 1000 and the second toy 2000 are deformed for the second time and both are transformed into the second form, thereby obtaining the deformed toy 3000 in the second form (animal form). In this case, first toy 1000 constitutes the body, limbs and tail of the animal, and second toy 2000 constitutes the head of the animal.

Specifically, referring to fig. 13, the fourth trigger structure 5b is movably disposed within the second housing 1b of the second toy 2000. The fourth trigger structure 5b is in the form of a strip plate. The fourth trigger structure 5b is located on the bottom plate 12b, and has one end abutting against the front inner wall of the upper cover 11b via the second elastic element 20 and the other end protruding from the rear end of the bottom plate 12 b. The second elastic element 20 is preferably a spring. The second elastic element 20 is mainly used for resetting the fourth triggering structure 5 b. The second magnetic attraction structure 200 is also located at the rear end of the second casing 1b and is disposed above the fourth triggering structure 5b at an interval. Specifically, a supporting portion extends upward from the rear end of the bottom plate 12b, and a recess portion facing the supporting portion (not shown) is provided in the upper cover 11 b. The second magnetic attraction structure 200 is placed on the supporting portion and inserted into the recess to position the second magnetic attraction structure 200.

Further, referring to fig. 13, the second trigger deforming assembly may further optionally include a protrusion 6 b. The fourth trigger structure 5b is provided with a slot 51b, and the protrusion 6b is disposed in the slot 51 b. When the fourth trigger structure 5b is triggered and moves forward relative to the second housing 1b, the protrusion 6b also moves forward along with the fourth trigger structure 5b, and the front end of the protrusion 6b extends out of the second housing 1b, and is shaped like a tooth and can be used as a tooth. At this point, the second toy 2000 completes the second transformation to the second configuration.

In addition, referring to fig. 14, in the first toy 1000, the second trigger structure 7a is provided at a bottom middle position of the first housing 1a and is movable within the first housing 1 a. Specifically, the second triggering structure 7a is also in the form of a long strip, the front end of which extends out of the first casing 1a, and the rear end of which is connected to the inner wall of the first casing 1a through the third elastic element 30. The third elastic element 30 is preferably a spring. The third elastic element 30 is mainly used for resetting the second triggering mechanism 7 a. The first magnetic attraction structure 100 is disposed at the front end of the second triggering structure 7a, and a recess 19a (see fig. 15) is correspondingly disposed on the first casing 1a, and the first magnetic attraction structure 100 is inserted into the recess 19a to be limited in the first casing 1 a.

Referring to fig. 14, the first toy 1000 may further optionally include a first locking portion and a second locking portion. The first locking portion is located at the front of the second trigger structure 7a and the second locking portion is located at the rear of the second trigger structure 7 a. The first locking portion and the second locking portion each include two insert plates 8a provided left and right.

Referring to fig. 15 and 16, at positions on both side surfaces of the first case 1a facing the insert plate 8a, third through holes 13a and fourth through holes 14a penetrating through the thickness direction thereof are provided. One end of the plug board 8a is connected with the second trigger structure 7a, and the other end of the plug board extends out of the first shell 1a through the third through hole 13a or the fourth through hole 14a and forms a second plug part. Accordingly, referring to fig. 17, the second rotating member 4a and the third rotating member 5a are provided with a second inserting position 45a capable of being matched with the second inserting portion on the side close to the first housing 1 a. The second plug site 45a is preferably of a recessed configuration. The second inserting portion is inserted into the second inserting position 45a to lock the second rotating member 4a or the third rotating member 5 a. Specifically, the two insert plates 8a of the first locking portion extend out of the third through hole 13a and lock the two second rotating members 4a, respectively, and the two insert plates 8a of the second locking portion extend out of the fourth through hole 14a and lock the two third rotating members 5a, respectively.

Referring again to fig. 14, the front and rear portions of the second triggering mechanism 7a are each provided with a guide post 71 a. One end of the plug board 8a connected with the second triggering structure 7a is provided with a guide hole, and the plug board 8a is movably sleeved on the guide post 71a of the second triggering structure 7a through the guide hole on the plug board 8a, so as to realize the connection between the plug board 8a and the second triggering structure 7 a. The guiding hole is shaped, and when the second triggering structure 7a moves inwards (i.e. moves backwards) relative to the first shell 1a, the left and right insertion plates 8a are driven to move towards the center in opposite directions. The insert plate 8a of the first locking portion is separated from the second rotating member 4a, unlocking the second rotating member 4 a. Subsequently, the insert plate 8a of the second locking portion is separated from the third rotating member 5a, unlocking the third rotating member 5 a. A limiting frame 18a (see fig. 15) covering the insert plate 8a may be optionally provided in the first housing 1a to guide the movement of the insert plate 8 a.

Between the two insert plates 8a of the first locking portion and between the two insert plates 8a of the second locking portion, fourth elastic elements 40 are connected, ensuring accurate resetting of the first locking portion and the second locking portion (see fig. 14). The fourth elastic element 40 is preferably a spring.

Alternatively, referring to fig. 15 and 6, first guide grooves 15a are opened at both side surfaces of the first housing 1a to guide the movement of the second rotating member 4 a. The first guide groove 15a is arc-shaped, and the rear end thereof is higher than the front end. Referring to fig. 17 and 18, the second rotating member 4a is provided with a first sliding end 41a on a side thereof adjacent to the first casing 1 a.

Referring to fig. 14, the first sliding end 41a is inserted into the first guide groove 15a, and a stopper portion 42a is fixedly connected to prevent the first sliding end 41a from falling off the first housing 1 a. A fifth elastic element 50 is disposed between the stopping portion 42a and the first housing 1 a. The fifth elastic element 50 is preferably a spring. One end of the fifth elastic element 50 is fixedly connected to the stopper portion 42a, and the other end is fixedly connected to the inner wall of the first housing 1 a. When the second rotating member 4a is locked by the first locking portion, the first sliding end 41a of the second rotating member 4a is located at the rearmost end of the first guide groove 15a, and the fifth elastic member 50 is placed in tension.

When the second trigger structure 7a is triggered and moves inward (i.e., moves backward) relative to the first housing 1a, the first locking portion unlocks the second rotating member 4 a. After the second rotating part 4a is unlocked, the fifth elastic element 50 drives the second rotating part 4a to slide along the first guiding sliding slot, and meanwhile, the second rotating part 4a is ensured to be attached to the first shell 1a until the second rotating part 4a slides to the foremost end of the first guiding slot 15 a. The second rotating member 4a is deformed into the front leg of the animal (see fig. 4 and 19) and supports the first housing 1a (i.e., the animal body) under the action of the fifth elastic element 50.

Alternatively, referring to fig. 15 and 16, the first housing 1a is further opened at both side surfaces thereof with second guide grooves 16a to guide the movement of the third rotating member 5 a. The second guide groove 16a is also arc-shaped, and has a rear end lower than a front end and a center coinciding with the axis of the transmission shaft 93 a.

Referring to fig. 17 and 18, the third rotating element 5a is provided with a second sliding end 51a on a side thereof adjacent to the first housing 1 a. The second sliding end 51a is inserted into the second guide groove 16 a. As can be seen from the above description of fig. 9, the third rotating member 5a is connected to the first housing 1a through the transmission shaft 93a and the first rear wheel 91a, and a torsion spring is further connected between the third rotating member 5a and the first housing 1 a. When the second locking portion locks the third rotating member 5a, the torsion spring connected between the third rotating member 5a and the first housing 1a is in a power accumulating state, and the second sliding end 51a is located at the rear end of the second guide groove 16 a. After the insertion plate 8a of the second locking portion is separated from the third rotating member 5a, and the third rotating member 5a is unlocked, it slides along the second guide groove 16a (i.e., rotates about the transmission shaft 93 a) until it reaches the foremost end of the second guide groove 16a under the action of the torsion spring (see fig. 4 and 19). The third rotating member 5a is deformed into the rear leg of the animal and supports the first housing 1a (i.e., the animal body) by the torsion spring. At this point, the first toy 1000 completes the second transformation and transitions to the second configuration.

When the second trigger structure 7a is triggered and moves backwards, the first locking part is driven to move and the second rotating part 4a is unlocked, and then the second locking part is driven to move and the third rotating part 5a is unlocked.

Alternatively, referring to fig. 17 and 20, after the first toy 1000 is deformed for the second time, in order to prevent the third rotating member 5a from rotating forward around the bottom end thereof, to allow the third rotating member 5a to effectively support the first housing 1a, and to stably maintain the first toy 1000 in the second configuration, the first toy 1000 may further optionally include a shape-fixing member 6 a. The shaped member 6a is located within the third rotating member 5a and engages the first toy 1000.

Specifically, referring to fig. 17, the shaping member 6a is provided with two connecting through holes, and correspondingly, the inner side of the third rotating member 5a is provided with two connecting posts. The connecting column is inserted into the connecting through hole and locked by a screw, so that the fixed connection of the shaping piece 6a and the third rotating piece 5a is realized. The shaped piece 6a is rotatable with the third rotating member 5a on the side of the first housing 1a relative to the first housing 1 a. The shape-fixing member 6a is further provided with an arc-shaped third guide groove 61 a. The center of the third guide groove 61a coincides with the center of the second guide groove 16 a.

Further, referring to fig. 16, a sliding connector 17a is fixedly disposed at an outer side of the first housing 1a, and the sliding connector 17a is located at a front lower portion of the second guide groove 16 a. The outermost end of the sliding connector 17a passes through the third guide groove 61a of the shape-defining member 6a to guide the movement of the shape-defining member 6 a.

The outermost end of the sliding contact piece 17a is preferably oval, and its dimension in the front-rear direction (i.e., the length direction) is large, and its dimension in the up-down direction (i.e., the thickness direction) is small. The dimension of the third guide groove 61a in the radial direction is larger than the dimension of the outermost end of the slide connector 17a in the up-down direction (i.e., the thickness direction) and smaller than the dimension of the outermost end of the slide connector 17a in the front-rear direction (i.e., the length direction). When the sliding connector 17a is installed, the radial direction of the third guide groove 61a is aligned with the vertical direction of the sliding connector 17a in parallel, so that the third guide groove 61a passes through the outermost end of the sliding connector 17a and is sleeved on the sliding connector 17 a. Then, the fixing member 6a is rotated such that the radial direction of the third guide groove 61a is parallel to the front-rear direction of the slide connector 17a, thereby rotatably connecting the fixing member 6a to the first housing 1 a.

When the third rotating member 5a is unlocked and the third rotating member 5a slides along the second guide groove 16a, the shaping member 6a also moves together with the third rotating member 5 a. When the second sliding end 51a of the third rotating member 5a moves to the front end of the second guiding sliding groove, the rear end of the third guiding groove 61a of the shape-defining piece 6a is just connected with the sliding connection piece 17a in a clamping manner, the shape-defining piece 6a is just placed on the sliding connection piece 17a (see fig. 20), the first shell 1a further supports the shape-defining piece 6a and the third rotating member 5a through the sliding connection piece 17a, so that the stability of the shape-defining piece 6a and the third rotating member 5a is ensured, the third rotating member 5a is prevented from rotating forwards around the bottom end thereof, and the first toy 1000 and the second toy 2000 are kept in the stable second form.

In the present embodiment, in the transformation toy 3000, the first form of the first toy 1000 and the first form of the second toy 2000 are first formed into the first form of the transformation toy 3000 by the cooperation of the first socket 121a and the first socket 3111 b.

The first form of the transformable toy 3000 is pulled backward, the first rear wheel 91a rotates clockwise by the friction force, and the return force gearbox 60 is charged with energy through the transmission shaft 93 a. When the first form of the transformable toy 3000 is released, the transmission shaft 93a and the first rear wheel 91a are driven by the return gear box 60 to rotate counterclockwise, and the first form of the transformable toy 3000 moves forward. In the process of moving forward, the driving gear 95a in the first toy 1000 rotates counterclockwise along with the transmission shaft 93a, the intermediate gear 96a rotates clockwise under the driving of the driving gear 95a, and due to the ratchet 97a, the driven gear 98a and the ratchet 97a rotate clockwise along with the driven gear 98 a. The driven gear 98a rotating clockwise is engaged with the first triggering structure 2a and drives the first triggering structure 2a to move away from the first rotating member 3a, and the first triggering structure 2a is separated from the first rotating member 3a to unlock the first rotating member 3 a. After the first rotating member 3a is unlocked, it rotates upward relative to the first casing 1a by the torsion spring, and the first toy 1000 is deformed for the first time.

The first rotating member 3a pushes the second toy 2000 forward in the process of rotating upward, and meanwhile, the first plugging portion 3111b is separated from the first plugging position 121a, and the second toy 2000 is separated from the first toy 1000.

The separated second toy 2000 continues to move forward by the thrust of the first rotating member 3a and its own inertia. Due to the action of the return tooth box 60, the first toy 1000 is faster, and the first toy 1000 can catch up and hit the rear end of the second toy 2000, so that the third triggering mechanism 32b extending from the rear end of the second toy 2000 is triggered. When the third triggering structure 32b is triggered, it moves forward relative to the second housing 1b and pushes against the latch 21b of the fourth rotating member 2b, so that the fourth rotating member 2b rotates outward and unlocks the fifth rotating member 3 b. After the two fifth rotating members 3b are unlocked, they are respectively rotated toward both sides of the second toy 2000 by the torsion spring, and the sixth rotating members 4b are unlocked. After the sixth rotating member 4b is unlocked, it is rotated upward of the second toy 2000 by the torsion spring. At this point, the second toy 2000 completes the first transformation.

After the first transformation of the second toy 2000 is completed, the rear end of the second casing 1b becomes the rear end of the second toy 2000. At this time, the fourth triggering structure 5b extending from the rear end of the second casing 1b is exposed to the rear end of the second toy 2000 (correspondingly, the first magnetic attraction structure 100 is provided at the front end of the first toy 1000); the second magnetic attraction structure 200 mounted on the rear end of the second casing 1b is also located at the rear end of the second toy 2000 (correspondingly, the second trigger structure 7a extends from the front end of the first toy 1000). The first toy 1000 continues to chase forward and hit the second toy 2000 under the action of the return force teethed box 60. When the distance between the first magnetic attraction structure 100 and the second magnetic attraction structure 200 is within the magnetic attraction range of the first magnetic attraction structure 100 and the second magnetic attraction structure 200, the first magnetic attraction structure 100 and the second magnetic attraction structure 200 attract each other, and the first toy 1000 and the second toy 2000 are combined. When the second trigger structure 7a and the fourth trigger structure 5b collide with each other and trigger each other, the first toy 1000 and the second toy 2000 are deformed for the second time and are transformed into the second form. Thereby, the deformation toy 3000 in the second form is obtained.

For the second transformation of the second toy 2000, when the fourth trigger structure 5b is triggered, the fourth trigger structure 5b and the protrusion 6b thereon move forward relative to the second housing 1b, and the protrusion 6b further protrudes from the second housing 1b to form the animal teeth.

For the second transformation of the first toy 1000, when the second trigger structure 7a is triggered, the second trigger structure 7a moves backward relative to the first housing 1 a. Under the drive of the first trigger structure 2a, the inserting plates 8a on the first locking part and the second locking part move towards the center and respectively unlock the second rotating part 4a and the third rotating part 5 a. After the second rotating part 4a is unlocked, it is driven by the fifth elastic element 50 to slide from the rear upper end of the first guide slot 15a to the front lower end of the first guide slot 15a, and is always attached to the first casing 1a to form two front legs of the animal. After the third rotating member 5a is unlocked, it is driven by the torsion spring to slide from the rear lower end of the second guide groove 16a to the front upper end of the second guide groove 16a, forming two rear legs of the animal.

During the movement of the third rotation element 5a, the setting element 6a, which is fixedly connected to the third rotation element 5a, also moves together with the third rotation element 5 a. The shape-fixing member 6a is provided with a third guide groove 61a, and correspondingly, the outer lower portion of the first housing 1a is provided with a sliding connector 17a engaged with the third guide groove 61 a. After the shaping piece 6a and the third rotating piece 5a finish moving, the shaping piece 6a just right overlaps the sliding connecting piece 17a through the rear end of the third guide groove 61a, the first shell 1a further supports the shaping piece 6a and the third rotating piece 5a through the sliding connecting piece 17a, and the stability of the whole structure after deformation is improved.

In this embodiment, the first toy 1000 and the second toy 2000 may be first combined into one, then divided into two, and finally combined into one, and continuously deformed in the process of being combined and separated, so that the two combined forms are different. The whole structure is simple, the action is smooth and layered, the deformed structure is stable, and the interestingness is strong.

It should be noted that, after obtaining the new toy of the second form, the first toy 1000 and the second toy 2000 can be pulled in opposite directions respectively, so that the first magnetic attraction structure 100 and the second magnetic attraction structure 200 are separated, and the distance between the first magnetic attraction structure and the second magnetic attraction structure is greater than the range capable of magnetic attraction, thereby realizing separation of the first toy 1000 and the second toy 2000. At the moment of separation, the second trigger structure 7a on the first toy 1000 and the fourth trigger structure 5b on the second toy 2000 are separated from each other. The second trigger structure 7a is reset by the third elastic element 30, and the fourth trigger structure 5b and the protrusion 6b are reset by the second elastic element 20.

When the second triggering structure 7a is reset, the inserting plates 8a on the first locking portion and the second locking portion are driven to move towards two sides, and the second triggering structure is accurately reset under the action of the fourth elastic element 40. Then, the second rotating member 4a of the first toy 1000 is manually rotated backward and engaged with the insert plate 8a of the first locking portion, and the second rotating member 4a is reset. The third rotating member 5a is then rotated backward so that the second sliding end 51a thereof slides to the rear lower end of the second guide groove 16a and is engaged with the insert plate 8a of the second locking portion, and the third rotating member 5a is reset. Then, the first rotating member 3a is rotated downward, so that the limiting notch 31a on the first rotating member is matched with the first triggering structure 2a, and the first rotating member 3a is reset. At this point, the second toy 2000 reverts to the first configuration.

The two fifth rotating members 3b of the second toy 2000 are manually rotated inward, the fifth rotating members 3b drive the reset fourth rotating members 2b to rotate inward until the fastening portions 21b of the fourth rotating members 2b are fastened to the second through holes of the fifth rotating members 3b, and the fifth rotating members 3b complete the reset. When inwards pulling the fifth rotation piece 3b, press down and detain two sixth rotation pieces 4b, make the fifth rotation piece 3b on joint portion and the sixth rotation piece 4b on the joint position cooperation, the sixth rotation piece 4b resets. At this point, the second toy 2000 reverts to the first configuration.

It should be noted that the torsion force of the torsion spring connected between the third rotating member 5a and the first housing 1a can be adjusted to be small, so that the rotating angle of the third rotating member 5a with respect to the first housing 1a becomes small (i.e., the second sliding end 51a does not move to the front end of the second guide groove 16a after the deformation of the third rotating member 5a is completed). The third rotating member 5a cannot be in a vertical state (i.e., two rear legs of the animal cannot stand up), so that sufficient supporting force cannot be provided to the transformable toy 3000, and in addition, the center of gravity of the transformable toy 3000 is relatively backward, so that the rear end of the transformable toy 3000 moves downward (at the same time, the front end of the transformable toy 3000 is lifted upward), and the third rotating member 5a is driven until the third rotating member 5a is in a horizontal state, so that the entire transformable toy 3000 is supported, and the state shown in fig. 21 is presented.

In addition, in other embodiments, the second triggering mechanism 7a may not be provided in the first toy 1000, i.e., the second rotating member 4a and the third rotating member 5a are not deformed, and the first toy 1000 is deformed only for the first time, but not for the second time; alternatively, the fourth trigger structure 5b may not be provided in the second toy 2000, i.e., the protrusion 6b is not deformed, and the second toy 2000 is deformed only for the first time without being deformed for the second time. Between first toy 1000 after the first deformation and the second toy 2000 after the first deformation, or between first toy 1000 after the first deformation and the second toy 2000 after the second deformation, or between first toy 1000 after the second deformation and the second toy 2000 after the first deformation, inhale structure 200 through first magnetism 100 and second magnetism, realize the fit, thereby obtain the deformation toy 3000 of another kind of form, as long as can make first toy 1000 and second toy 2000 unite two into one earlier, divide into two again, and finally unite two into one again can.

In other embodiments, the third triggering mechanism 32b (and optionally the fourth triggering mechanism 5b at this time) may not be provided in the second toy 2000, and the second magnetic attraction structure 200 may be provided at the rear end of the second toy 2000, and optionally the second triggering mechanism 7a may be provided in the first toy 1000 at this time. At this time, the torsion of the torsion spring connected between the first rotating member 3a and the first casing 1a is adjusted to adjust the pushing force of the first rotating member 3a to the second toy 2000 when the first rotating member rotates upward, so as to adjust the distance that the second toy 2000 is pushed down from the first toy 1000, so that the distance is in the magnetic attraction range of the first magnetic structure and the second magnetic structure (at this time, the return force gear box 60 is not needed to apply the driving force to the first toy 1000), the two separated parts can be combined again through the magnetic attraction force, thereby ensuring that the first toy 1000 and the second toy 2000 can be firstly combined into one, then divided into two, and finally combined into one again.

In addition, in other embodiments, the first rotating member 3a and the first casing 1a may be pivotally connected only by the pin, and no torsion spring is disposed therebetween, and the first triggering structure 2a is disposed above the driven gear 98a, and the first triggering structure 2a is abutted only against the first rotating member 3 a. Thus, when the driven gear 98a rotates clockwise and engages with the first triggering structure 2a, the first triggering structure 2a is driven to move backward, and the first triggering structure 2a further drives the first rotating member 3a to rotate relative to the first casing 1a, so as to push the second toy 2000 away from the first toy 1000.

It is to be noted that the foregoing is only illustrative of the preferred embodiments of the present invention and the technical principles employed. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail by the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the spirit of the present invention, and the scope of the present invention is determined by the scope of the appended claims.

Claims (17)

1. A transformable toy, wherein the transformable toy (3000) is a composite toy capable of multi-stage transformation, comprising a first toy (1000) and a second toy (2000), the first toy (1000) and the second toy (2000) each having an initial first configuration and a final second configuration;

said second toy (2000) in a first configuration being lockable to said first toy (1000) in a first configuration, said transformable toy (3000) being in an initial assembled state;

the transformable toy (3000) is stored energy and moves forwards, and in the process of the forward movement, the second toy (2000) is separated from the first toy (1000) forwards, and the transformable toy is in a middle separation state;

the first toy (1000) moves forward to collide with the second toy (2000), both of which are transformed into a second state, and the first toy (1000) and the second toy (2000) are separated or integrated, the transformed toy being in a final separated transformed state or integrated transformed state.

2. The deformation toy of claim 1, wherein the first toy (1000) is provided with a first triggering deformation component, a locking component and an energy storage component, in a first state, the first toy (1000) moves backwards to store energy to the energy storage component, the energy storage component is connected with the locking component, after the energy storage is finished, the first toy (1000) moves forwards under the driving of the energy storage component, in the process of moving forwards, the energy storage component drives the locking component to unlock, the first triggering deformation component is pressed by external force, and the first toy (1000) changes into a second state;

the second toy (2000) of the first shape is locked on the first toy (1000) of the first shape through the locking assembly so that the transformable toy is in an initial state, when the locking assembly is unlocked, the second toy (2000) is forwards separated from the first toy (1000) so that the transformable toy is in a separated state, and a second triggering transformation assembly is arranged on the second toy (2000);

when the first toy (1000) moves forward to collide with the second toy (2000), the first triggering deformation component and the second triggering deformation component are triggered by the second toy (2000) and the first toy (1000), the first triggering deformation component and the second triggering deformation component are changed into a second form, and the deformation toy is in a deformation state.

3. The transformable toy of claim 2, wherein the first magnetic attraction structure (100) is arranged at the front end of the first toy (1000), the second magnetic attraction structure (200) is arranged in the second toy (2000), and when the first toy (1000) moves forward to collide with the second toy (2000) and is transformed, the first magnetic attraction structure (100) and the second magnetic attraction structure (200) attract each other.

4. A transformable toy according to claim 2 or 3 wherein the first toy (1000) is further provided with a first rotating member (3a), the non-end position of the first rotating member (3a) is pivotally connected to the first toy (1000) by a torsion spring, the locking assembly comprises a limit projection provided at the front end of the first rotating member (3a) and protruding from the upper end of the first toy (1000), the locking assembly further comprises a limit notch (31a) provided at the rear end of the first rotating member (3a) and a first elastic trigger structure capable of engaging with or disengaging from the limit notch (31a) to lock or unlock the locking assembly.

5. The transformable toy of claim 4, wherein the first elastic trigger structure comprises a first trigger structure (2a) and a first elastic element (10), one end of the first trigger structure (2a) is connected with the first elastic element (10), the other end can be matched with or separated from the limit notch (31a), and the first trigger structure (2a) can be also engaged with or separated from the output end of the energy storage component;

when the locking assembly is separated, the first trigger structure (2a) is matched with the limiting notch (31a) under the action of the first elastic element (10), and the locking assembly is locked;

when the first trigger structure (2a) is meshed with the limiting notch (31a), the first rotating piece (3a) rotates forwards relative to the first toy (1000) under the action of the torsion spring, the locking assembly is unlocked, and the second toy (2000) is pushed forwards away from the first toy (1000) by the first rotating piece (3 a).

6. A transformable toy according to claim 5, characterized in that the energy accumulating assembly comprises a return gearbox (60) and a transmission structure, the transmission structure comprises a driving gear (95a), an intermediate gear (96a), a ratchet wheel (97a) and a driven gear (98a), the driving gear (95a) is coaxially and fixedly connected with an output shaft of the return gear box (60), the intermediate gear (96a) is provided with external teeth engaged with the drive gear (95a) and internal teeth engaged with the ratchet gear (97a), the driven gear (98a) is coaxially and fixedly connected with the ratchet wheel (97a), a first tooth structure is arranged on part of the driven gear (98a) in the circumferential direction, the first trigger structure (2a) is arranged on one side of the driven gear (98a), and a second tooth structure capable of being meshed with the first tooth structure is arranged on the first trigger structure;

when the ratchet wheel (97a) is static, the first tooth structure is separated from the second tooth structure, and the first trigger structure (2a) is matched with the limit notch (31 a);

when the ratchet wheel (97a) rotates along with the intermediate gear (96a), the first tooth structure can be meshed with the second tooth structure, and the first trigger structure (2a) is separated from the limiting notch (31 a).

7. A transformable toy according to claim 6 wherein said energy storage assembly further comprises a first rear wheel (91a) rotatably connected to said first toy (1000), said first rear wheel (91a) being fixedly connected coaxially to an output shaft of said return gearbox (60), said first rear wheel (91a) rotating and storing energy in said return gearbox (60) through said output shaft, moving said first toy (1000) backwards.

8. A transformable toy according to claim 3, wherein the first toy (1000) comprises a first housing (1a), the first triggering transformable component being connected to the first housing (1a), the first magnetic attraction structure (100) being provided at a front end of the first housing (1 a).

9. The transformable toy of claim 8, wherein the first triggered transforming assembly comprises:

the two second rotating pieces (4a) are arranged and are respectively arranged at the left side and the right side of the first shell (1a), and the two second rotating pieces (4a) are pivoted with the first shell (1 a);

the two third rotating parts (5a) are respectively arranged at the left side and the right side of the first shell (1a), the two third rotating parts (5a) are pivoted with the first shell (1a), and the third rotating parts (5a) are positioned at the rear sides of the second rotating parts (4 a);

the second elastic trigger structure is movably arranged in the first shell (1a) and extends out of the front end of the first shell (1 a);

the first locking part is arranged in the first shell (1a) and matched with the second elastic triggering structure, so that the first locking part can be extended or folded along the left-right direction of the first shell (1 a);

the second locking part is arranged in the first shell (1a) and matched with the second elastic triggering structure, so that the second locking part can be expanded or folded along the left-right direction of the first shell (1 a);

when the second elastic triggering structure is not triggered, the first locking part extends, two ends of the first locking part respectively extend from the left side and the right side of the first shell (1a) and are matched with the second rotating part (4a) to lock the second rotating part (4a), the second locking part extends, two ends of the second locking part respectively extend from the left side and the right side of the first shell (1a) and are matched with the third rotating part (5a) to lock the third rotating part (5 a);

when the second elastic trigger structure is triggered, the first locking part is folded, two ends of the first locking part are separated from the second rotating part (4a), the second rotating part (4a) is unlocked and rotates, the second locking part is folded, two ends of the second locking part are separated from the third rotating part (5a), and the third rotating part (5a) is unlocked and rotates.

10. The transformable toy of claim 9, wherein the first housing (1a) is provided with first guide grooves (15a) on both left and right sides thereof, the second rotating member (4a) is provided with first sliding ends (41a), the first sliding ends (41a) slidably pass through the first guide grooves (15a) and are connected to the inner wall of the first housing (1a) through fifth elastic elements (50), and when the second rotating member (4a) is unlocked, the second rotating member (4a) slides along the first guide grooves (15a) under the action of the fifth elastic elements (50);

the left and right sides of first casing (1a) still all is equipped with second guide way (16a), the third rotates and is equipped with second slip end (51a) on piece (5a), second slip end (51a) passes slidable second guide way (16a), the second rotate piece (4a) with be connected with the torsional spring between first casing (1a), after the unblock, the second rotates piece (4a) and is in follow under the effect of torsional spring second guide way (16a) slide.

11. A transformable toy according to claim 9 or 10, characterized in that when the first toy (1000) is advanced to collide with the second toy (2000), the front end portion of the second elastic trigger structure protruding out of the first casing (1a) is pressed by the second toy (2000), and the first trigger transforming component is triggered.

12. The transformable toy according to claim 3, wherein the second toy (2000) includes a second housing (1b), the second triggering transformable assembly includes two fourth rotating members (2b) and two fifth rotating members (3b) both pivotally connected to the second housing (1b), the two fifth rotating members (3b) are provided at a rear end of the second housing (1b), the fifth rotating members (3b) further include a third triggering structure movably provided at the fifth rotating members (3b) and protruding from a rear end of the fifth rotating members (3b), the fourth rotating members (2b) are fittable to and lockable with a front end of the third triggering structure to lock the fifth rotating members (3b) to trigger the third triggering structure, the fourth rotating members (2b) are rotated and separated from the fifth rotating members (3b), the two fifth rotating members (3b) are unlocked and rotated to the left and right with respect to the second housing (1b), respectively.

13. The transformable toy of claim 12, wherein the second triggering transformation assembly further comprises a sixth rotation piece (4b), the sixth rotation piece (4b) is also provided at the rear end of the second housing (1b) and is pivotally connected to the second housing (1b), the sixth rotation piece (4b) is provided in the middle of two of the fifth rotation pieces (3b), the fifth rotation piece (3b) can be engaged with the sixth rotation piece (4b) to lock the sixth rotation piece (4b), when the fifth rotation piece (3b) is unlocked and rotated, the fifth rotation piece (3b) is separated from the sixth rotation piece (4b), and the sixth rotation piece (4b) is unlocked and rotated upward with respect to the second housing (1 b).

14. A transformable toy according to claim 13, wherein when the first toy (1000) is moved forward to collide with the second toy (2000), the portion of the third trigger structure extending beyond the rear end of the fifth rotating member (3b) is pressed by the first toy (1000), and the second trigger transforming component is triggered.

15. A transformable toy as claimed in claim 14 wherein the second magnetic structure (200) is provided at the rear end of the second housing (1b) and the first magnetic structure (100) and the second magnetic structure (200) are engaged after the first toy (1000) is moved forward to collide with the second toy (2000) and the second triggering transformable component is triggered.

16. The transformable toy of claim 15, wherein the second triggered transforming assembly further comprises a fourth elastic triggering structure movably provided in the second housing (1b) and protruding from a rear end of the second housing (1b), and a protrusion (6b) also provided in the second housing (1b) and protruding from a front end of the second housing (1b), the protrusion (6b) being engaged with the fourth elastic triggering structure and being movable together with the fourth triggering structure to extend forward or retract with respect to the front end of the second housing (1 b).

17. A transformable toy according to claim 16 wherein the first magnetically attractive structure (100) and the second magnetically attractive structure (200) when attracted, the first toy (1000) triggers the fourth resilient trigger structure, the protrusion (6b) moves forward with the fourth trigger structure, the protrusion (6b) extends forward relative to the front end of the second housing (1 b).

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