CN212662702U

CN212662702U - Transformable toys

Info

Publication number: CN212662702U
Application number: CN202021274724.2U
Authority: CN
Inventors: 刘国庆
Original assignee: Kaihua Industrial Co ltd
Current assignee: Kaihua Industrial Co ltd
Priority date: 2020-06-09
Filing date: 2020-07-03
Publication date: 2021-03-09
Anticipated expiration: 2030-07-03
Also published as: US20210379505A1; TWI717291B; TW202146093A

Abstract

A transformable toy comprises a telescopic assembly, a bottom frame, a top frame and an elastic assembly. The telescopic assembly comprises a bottom plate and a top plate opposite to the bottom plate, and can be operated to be telescopic along the up-down direction. The bottom frame is arranged on the bottom plate and comprises a lower clamping hook. The top frame is arranged on the top plate and comprises an upper clamping hook which can be detachably clamped on the lower clamping hook. The elastic component is arranged in the telescopic component and applies elastic force for enabling the top plate to be far away from the bottom plate. The top frame can be applied with a downward pressure to clamp the upper clamping hook on the lower clamping hook, and the lower clamping hook can be applied with an upward pressure opposite to the downward pressure to separate the lower clamping hook from the upper clamping hook. Therefore, the convenience of operating the lower clamping hook and the upper clamping hook in the clamping and releasing process can be provided.

Description

Deformable toy

Technical Field

The utility model relates to a toy, in particular to a deformable toy which can be deformed between different states.

Background

The existing toy capable of deforming among different forms is buckled on a plate of a toy body through a buckling piece, so that the toy body is kept in a compressed state. However, to fasten the fastening member to the plate or to move the fastening member away from the plate, the fastening member is pulled by the user to be bent and deformed, so that the fastening member is inconvenient to operate and cannot be automatically released from the plate in cooperation with the playing method of the toy.

Furthermore, because the elastic member of the toy and the connection mode between the toy bodies make the direction of the elastic member that deforms in a stretching manner is different from the direction of the toy bodies in a stretching manner, the elastic member cannot uniformly apply elastic force to the toy bodies, and the toy bodies cannot be smoothly bounced off by the elastic force of the elastic member and deform to an bounced off state.

Disclosure of Invention

One of the objects of the present invention is to provide a transformable toy which can overcome at least one of the drawbacks of the background art.

The purpose of the utility model and the solving of the background technical problem are realized by adopting the following technical proposal, the deformable toy provided by the utility model comprises a telescopic component, a bottom frame, a top frame and an elastic component, the telescopic assembly comprises a bottom plate and a top plate opposite to the bottom plate, the telescopic assembly can be operated to be telescopic along the up-down direction, the bottom frame is arranged on the bottom plate and comprises at least one lower clamping hook, the top frame is arranged on the top plate and comprises at least one upper clamping hook which can be detachably clamped on the lower clamping hook, the elastic component is arranged in the telescopic component and applies elastic force to the telescopic component to enable the top plate to be far away from the bottom plate, the top frame can be applied with a downward pressure to clamp the upper clamping hook on the lower clamping hook, and the lower clamping hook can be applied with an upward pressure opposite to the downward pressure to separate the lower clamping hook from the upper clamping hook.

The utility model discloses a deformable toy, the pothook has the last inclined plane towards the top down, it has the lower inclined plane towards the below to go up the pothook, the inclined plane is used for contacting down go up the inclined plane and can slide on it in order to impel pothook bending deformation down, and then makes the pothook can block in down go up the pothook.

The utility model discloses a deformable toy, the pothook has the cantilever down, and the arm of pulling, the arm of pulling connect in integratively cantilever one end be used for the card pull in go up the pothook, the bottom of the arm of pulling is used for bearing go up pressure in order to impel cantilever bending deformation and then drive the arm of pulling breaks away from go up the pothook.

The utility model discloses a deformable toy, the arm of blocking has the arm section of blocking, and atress arm section, the arm section of blocking connect in cantilever one end and protruding stretching the top surface of cantilever is used for blocking in go up the pothook, the atress arm section form in the bottom of arm section of blocking and protruding stretching the bottom surface of cantilever is used for bearing go up pressure.

The utility model discloses a deformable toy, the arm section of blocking is followed the first length that upper and lower direction was got is greater than the atress arm section is followed the second length that upper and lower direction was got.

The utility model discloses a deformable toy, the atress arm section has and is located the bottom and is used for bearing the pointed end portion of upper pressure.

The utility model discloses a deformable toy, the arm section of blocking in has the lower hook portion that is close to on the top, hook portion has the last inclined plane towards the top down, it has the last hook portion that is close to the bottom to go up the pothook, it has the lower inclined plane towards the below to go up hook portion, the inclined plane is used for contacting down go up the inclined plane and can slide on it in order to impel the arm buckling deformation of blocking in, and then make hook portion down can block in go up hook portion.

The utility model discloses a deformable toy, the chassis includes two lower pothooks, the pothook is along essentially perpendicular to down the reverse setting of transverse direction and looks interval of upper and lower direction, the roof-rack includes two and goes up the pothook, go up the pothook along the reverse setting of transverse direction and looks interval, go up the pothook respectively for the card drag in lower pothook.

The utility model discloses a deformable toy, the chassis still includes that the interval is located separation baffle between the pothook down, it is used for blockking the correspondence to separate the baffle go up the pothook, each it is used for wearing to locate to correspond to go up the pothook down the pothook with separate between the baffle.

The utility model discloses a deformable toy, the chassis includes the chassis body, and combines the support body down, the chassis body has the bedplate, and a plurality of protruding locating the top surface of bedplate just wears to locate the clip of bottom plate, the bedplate butt in the bottom surface of bottom plate is formed with two perforation, combine the support body down have the butt in the top surface of bottom plate and quilt the annular slab of clip buckle, and connect in the annular slab the pothook down, the pothook is worn to locate respectively perforation and the protruding extension of part the bottom surface of bedplate.

The utility model discloses a deformable toy, the roof-rack includes the roof-rack body, and combines the support body on reaching, the roof-rack body has the roof-rack, and two protruding locating the clip of the bottom surface of roof-rack, the roof-rack butt in the top surface of roof, on combine the support body to have the pillar, and protruding locating the bottom of pillar go up the pothook, the pillar butt in the bottom surface of roof, the clip buckle in the bottom of pillar.

The utility model discloses a deformable toy, the elastic component including set up in the flexible subassembly and exert to it the spring of elasticity, the spring can be followed the flexible deformation of upper and lower direction.

The utility model discloses a deformable toy, flexible subassembly includes the lower telescopic body, goes up the telescopic body, and the coupling unit, the lower telescopic body has the bottom plate, and is located the upper plate of bottom plate top, it has the stack in to go up the telescopic body the hypoplastron on the top of upper plate, and be located the hypoplastron top the roof, the coupling unit will the upper plate reaches the hypoplastron link together and with the upper plate reaches the hypoplastron defines the passageway jointly, the passageway is used for supplying lower pothook reaches go up the pothook and wear to establish, elastic component including set up in first spring in the lower telescopic body, first spring butt in the chassis with between the coupling unit and can follow the flexible deformation of upper and lower direction.

The utility model discloses a deformable toy, the chassis is formed with positioning groove down, the linkage unit is formed with positioning groove, first spring have the card pull in lower tip in the positioning groove down, and the card pull in go up the upper end in the positioning groove.

The utility model discloses a deformable toy, elastic component still including set up in go up flexible internal second spring, second spring butt in the linkage unit with between the roof and can follow the flexible deformation of upper and lower direction.

The utility model discloses a deformable toy, the linkage unit is formed with positioning groove down, the roof-rack is formed with positioning groove, the second spring have the card pull in lower tip in the positioning groove down, and the card pull in go up the upper end in the positioning groove.

The beneficial effects of the utility model reside in that: the lower hooks can be automatically and respectively clamped on the upper hooks by applying the lower pressure to the top frame. In an operation mode in accordance with the play of the transformable toy, the lower hook is automatically released from the upper hook by applying the upper pressure to the tip portion of the lower hook. Under the self-operation mode of a user, the user only needs to operate the force application of the force-bearing arm section along a single direction to release the lower clamping hook from the upper clamping hook, and the operation is very simple and convenient. Therefore, the convenience of operating the lower clamping hook and the upper clamping hook in the clamping and releasing process can be provided. The first spring and the second spring of the elastic component can uniformly apply elastic force to the telescopic component and smoothly bounce the telescopic component, so that the deformable toy can be quickly deformed into the stretching state.

Drawings

FIG. 1 is a perspective view of one embodiment of a transformable toy of the present invention, illustrating the transformable toy in an extended state;

FIG. 2 is an exploded perspective view of the embodiment illustrating the assembly relationship between a telescoping assembly, a bottom frame, a top frame, and a resilient assembly;

FIG. 3 is a cross-sectional view taken along line III-III of FIG. 1 illustrating the assembled relationship between the telescoping assembly, the base frame, the top frame, and the resilient assembly;

FIG. 4 is a bottom view of the lower link of the embodiment illustrating the connection between the lower link and a first spring;

FIG. 5 is a top view of an upper link of the embodiment, illustrating the connection relationship between the upper link and a second spring;

fig. 6 is a plan view of a lower coupling frame body of the embodiment, illustrating a coupling relationship between the lower coupling frame body and the first spring;

FIG. 7 is a fragmentary cross-sectional view of the embodiment, illustrating the connection between the upper frame and the second spring;

FIG. 8 is a cross-sectional view of the embodiment illustrating the application of a compressive force to the top frame;

FIG. 9 is a cross-sectional view of the embodiment showing the transformable toy in a collapsed state and two lower hooks each in a detent position; and

fig. 10 is a cross-sectional view of the embodiment, illustrating that an upper pressure is applied to a tip portion of each of the lower hooks, and each of the lower hooks is in a release position.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings and examples.

Before the present invention is described in detail, it should be noted that in the following description, like elements are represented by like reference numerals.

Referring to fig. 1, an embodiment of the transformable toy 100 of the present invention includes a telescopic member 1, a bottom frame 2, a top frame 3, and an elastic member 4.

Referring to fig. 2 and 3, the telescopic assembly 1 includes a lower telescopic body 11, an upper telescopic body 12, and a connecting unit 13. The lower telescopic body 11 includes a lower plate 110, an upper plate 111, and a plurality of connecting pieces 112. The lower plate 110 has a bottom plate 113, and a plurality of lower connection plates 114 connected to the outer periphery of the bottom plate 113 in a bendable manner. The bottom plate 113 is formed with a centrally located opening 115 and a plurality of through holes 116 surrounding the outer periphery of the opening 115. The upper plate 111 is located above the lower plate 110 along an up-down direction Z, and the upper plate 111 has a structure similar to that of the lower plate 110 and has an upper plate 117 located above the bottom plate 113, and a plurality of upper connecting plates 118 connected to an outer periphery of the upper plate 117 in a bendable manner. The upper plate 117 is formed with a centrally located opening 119. An outer side of each of the upper connecting plates 118 abuts an outer side of the corresponding lower connecting plate 114. Each connecting piece 112 is, for example, an adhesive tape, and each connecting piece 112 adheres the corresponding upper connecting plate 118 and the corresponding lower connecting plate 114 together. Therefore, each upper connecting plate 118 can be pivoted with the corresponding lower connecting plate 114 through the corresponding connecting piece 112, so that each upper connecting plate 118 and the corresponding lower connecting plate 114 can approach or depart from each other.

The structure of the upper telescopic body 12 is similar to that of the lower telescopic body 11, but the volume of the upper telescopic body 12 is slightly smaller than that of the lower telescopic body 11. The upper telescopic body 12 is located above the lower telescopic body 11 along the up-down direction Z and includes a lower plate 120, an upper plate 121, and a plurality of connecting pieces 122. The lower plate 120 has a lower plate 123 and a plurality of lower connection plates 124 bendably connected to the outer periphery of the lower plate 123. The lower plate 123 is stacked on the top of the upper plate 117 and is formed with a centrally located opening 125, and the opening 125 is connected to the top of the opening 119. The upper plate 121 is located above the lower plate 120 along the up-down direction Z, and the upper plate 121 has a structure similar to that of the lower plate 120 and has a top plate 126 located above the lower plate 123, and a plurality of upper connection plates 127 bendably connected to the outer periphery of the top plate 126. The top plate 126 is formed with two through holes 128, and the through holes 128 are arranged at intervals along a first transverse direction X substantially perpendicular to the up-down direction Z, for example, a front-back direction. An outer side edge of each of the upper connection plates 127 abuts against an outer side edge of the corresponding lower connection plate 124. Each connecting piece 122 is, for example, an adhesive tape, and each connecting piece 122 adheres the corresponding upper connecting plate 127 and the corresponding lower connecting plate 124 together. Therefore, each upper connecting plate 127 can be pivoted with the corresponding lower connecting plate 124 through the corresponding connecting piece 122, so that each upper connecting plate 127 and the corresponding lower connecting plate 124 can approach or depart from each other.

In the present embodiment, the lower plate 110 and the upper plate 111 of the lower telescopic body 11 and the lower plate 120 and the upper plate 121 of the upper telescopic body 12 are made of paper, but may be made of plastic. In addition, the bottom plate 113 and the upper plate 117 of the lower telescopic body 11 and the lower plate 123 and the top plate 126 of the upper telescopic body 12 are all polygonal plates, such as a hexagon, for example, but not limited thereto, and the number of sides of the polygon may be six or less or more as required.

Referring to fig. 2, 3 and 4, the connection unit 13 includes a lower connection member 130 and an upper connection member 131. The lower connecting member 130 has a ring plate 132, a plurality of hooks 133, and an upper positioning block 134. The annular plate 132 abuts against the bottom surface of the upper plate 117 and is formed with a central opening 135, and the opening 135 is communicated with the bottom end of the opening 119. The hooks 133 are protruded from the top surface of the annular plate 132 and located around the opening 135, and the hooks 133 are arranged at equal angles and spaced from each other. The upper positioning block 134 is protruded from the bottom surface of the annular plate 132 and is formed with an upper positioning engaging groove 136.

Referring to fig. 2, 3 and 5, the upper connecting member 131 has an annular plate 137 and a lower positioning block 138. The annular plate 137 abuts against the top surface of the lower plate 123 and is formed with a centrally located opening 139, and the opening 139 is connected to the top end of the opening 125. The lower positioning block 138 is protruded from the top surface of the annular plate 137 and is formed with a lower positioning engaging groove 140. The opening 139 of the upper connecting member 131, the opening 125 of the lower plate 123, the opening 119 of the upper plate 117 and the opening 135 of the lower connecting member 130 together define a passage 14 communicating between the lower telescopic body 11 and the upper telescopic body 12.

The annular plate 132 of the lower connecting member 130 and the annular plate 137 of the upper connecting member 131 are used to clamp the upper plate 117 of the lower telescopic body 11 and the lower plate 123 of the upper telescopic body 12 together, and the hook 133 of the lower connecting member 130 is inserted into the opening 119, the opening 125 and the opening 139 and is fastened to the top surface of the annular plate 137 of the upper connecting member 131, so that the connecting unit 13 can firmly connect and fix the upper plate 117 and the lower plate 123 together. Thereby, the telescopic assembly 1 can be operated to be telescopic along the up-down direction Z.

Referring to fig. 2 and 3, the base frame 2 includes a base frame body 21 and a lower coupling frame body 22. The base frame 21 has a seat plate 210, a separating baffle 211, and a plurality of hooks 212. The seat plate 210 abuts against the bottom surface of the bottom plate 113 and is formed with two through holes 213, the through holes 213 are spaced apart along a second transverse direction Y, which is substantially perpendicular to the up-down direction Z and the first transverse direction X, for example, a left-right direction. The partition 211 is protruded from the center of the top surface of the seat plate 210 and is spaced between the through holes 213. The hooks 212 are convexly arranged on the top surface of the seat plate 210 and arranged at equal intervals, and the hooks 212 are respectively inserted into and clamped in the through holes 116.

Referring to fig. 2, 3 and 6, the lower combining frame 22 has a ring plate 220, two lower hooks 221 and a lower positioning block 222. The annular plate 220 abuts against the top surface of the bottom plate 113 and is formed with an opening 223 and a plurality of fastening holes 224. The opening 223 is connected to the top end of the opening 115 and is used for the partition 211 to pass through. The locking holes 224 are arranged at equal angular intervals and located around the opening 223, and the locking holes 224 are respectively used for the hooks 212 to penetrate and lock.

The lower hooks 221 are integrally connected to the annular plate 220 and are oppositely disposed and spaced apart along the second transverse direction Y, and the lower hooks 221 are located on the opposite side of the opening 223 and the opposite side of the separating baffle 211. Each of the lower hooks 221 has a cantilever 225 and a latch arm 226. The cantilever 225 extends along the second transverse direction Y, and the outer end of the cantilever 225 is integrally connected to the annular plate 220 and forms two slits 227 spaced apart from the annular plate 220 along the first transverse direction X. The latching arm 226 has a latching arm section 228 and a force-bearing arm section 229. The latch arm segment 228 is integrally connected to the inner end of the cantilever arm 225 and protrudes out of the top surface of the cantilever arm 225. The latching arm 228 has a lower hook 230 adjacent to the top end, and the lower hook 230 has an upward inclined surface 231. The force-receiving arm segment 229 forms the bottom end of the latching arm segment 228 and protrudes out of the bottom surface of the cantilever 225. The force-bearing arm segment 229 is disposed through the corresponding through hole 213 and partially protrudes out of the bottom surface of the seat plate 210. The force-receiving arm segment 229 has a tip 232 protruding out of the bottom surface of the seat plate 210, and the tip 232 is used for bearing an upper pressure P (as shown in fig. 10) to make the corresponding cantilever 225 able to bend and deform to drive the latch arm segment 228 to rotate. In this embodiment, a first length L1 of the latching arm segment 228 taken along the up-down direction Z is greater than a second length L2 of the force-receiving arm segment 229 taken along the up-down direction Z. The lower positioning block 222 is protruded from the top surface of the annular plate 220 and forms a lower positioning engaging groove 233.

The chassis body 21 is respectively inserted into and engaged with the engaging holes 224 through the hooks 212, so that the chassis body 21 and the lower engaging body 22 can be prevented from rotating relatively. The chassis body 21 is fastened to the top surface of the annular plate 220 through the clasp 212, so that the chassis body 21 and the lower combined chassis body 22 can be prevented from being separated from each other. The base plate 210 of the chassis body 21 and the annular plate 220 of the lower coupling body 22 are used to clamp the base plate 113 of the lower telescopic body 11 together, and the hooks 212 of the chassis body 21 are respectively inserted into and engaged with the through holes 116 and the engaging holes 224 and are fastened to the top surface of the annular plate 220 of the lower coupling body 22, so that the chassis 2 can be stably fixed on the base plate 113.

Referring to fig. 2, 3 and 7, the top frame 3 includes a top frame body 31 and an upper combining frame body 32. The top frame 31 has a top plate 310 and three

hooks

311, 312. The top plate 310 abuts the top surface of the top plate 126. The

hooks

311, 312 are protruded from the bottom surface of the top plate 310, and one of the hooks 311 and the other two hooks 312 are spaced apart from each other along the first horizontal direction X. The hook 311 is inserted through and engaged with a corresponding one of the through holes 128. The hooks 312 are inserted through and engaged with the other corresponding through hole 128, and the hooks 312 are spaced apart from each other with a gap 313 formed therebetween.

The upper combining frame 32 has a base 320 and two upper hooks 321. The base pillar 320 abuts against the bottom surface of the top plate 126. The outer peripheral surface of the base pillar 320 is recessed to form an upper positioning slot 322, and the upper positioning slot 322 extends to the top surface of the base pillar 320. The upper hooks 321 are protruded at the bottom of the base pillar 320 and are oppositely arranged along the second transverse direction Y and spaced from each other. Each of the upper hooks 321 has an upper hook 323 adjacent to the bottom end, and the upper hook 323 can be detachably engaged with the lower hook 230 of the corresponding lower hook 221. The upper hook 323 has a downward inclined surface 324, and the lower inclined surface 324 is used to contact the corresponding upper inclined surface 231 of the lower hook 230 and can slide thereon to cause the latch arm 226 to bend and deform, so that the lower hook 230 can be latched to the corresponding upper hook 323.

The top frame body 31 is respectively clamped at the bottom end of the base column 320 of the upper combining frame body 32 through the

hooks

311 and 312 and is blocked by the upper hooks 321, so that the top frame body 31 and the upper combining frame body 32 can be prevented from rotating relatively and being separated from each other. The top plate 126 of the upper telescopic body 12 is clamped by the top plate 310 of the top frame body 312 and the base pillar 320 of the upper combining frame body 32, and the

hooks

311 and 312 of the top frame body 31 are respectively inserted and clamped in the through hole 128 and fastened at the bottom end of the base pillar 320 of the upper combining frame body 32, so that the top frame 3 can be stably fixed on the top plate 126.

Referring to fig. 2, 3, 4 and 6, the elastic element 4 includes a first spring 41 and a second spring 42. The first spring 41 is a compression spring capable of being deformed in a telescopic manner along the vertical direction Z, and is disposed in the lower telescopic body 11 and sleeved on the latching arm section 228 of the lower latching hook 221. The first spring 41 abuts between the top surface of the annular plate 220 of the base frame 2 and the bottom surface of the annular plate 132 of the connection unit 13. The first spring 41 has a lower end 411 and an upper end 412. The lower end 411 is engaged with the lower positioning engaging groove 233 of the lower positioning block 222, and the upper end 412 is engaged with the upper positioning engaging groove 136 of the upper positioning block 134. Thereby, the first spring 41 can be stably positioned between the lower coupling frame 22 and the lower link 130, and can apply an elastic force to the lower link 130 away from the lower coupling frame 22.

Referring to fig. 2, 3, 5 and 7, the second spring 42 is a conical spring capable of expanding and contracting along the vertical direction Z, and is disposed in the upper telescopic body 12 and sleeved on the upper combining frame body 32. The second spring 42 abuts between the top surface of the annular plate 137 of the upper connecting member 131 and the bottom surface of the top plate 126. The second spring 42 has a lower end 421 and an upper end 422. The lower end 421 is engaged with the lower positioning engaging groove 140 of the lower positioning block 138, and the upper end 422 is engaged with the upper positioning engaging groove 322 of the upper coupling frame 32. Thereby, the second spring 42 can be stably positioned between the upper connector 131 and the upper coupling frame body 32, and can apply an elastic force to the upper frame 3 away from the upper connector 131.

Referring to fig. 3, the elastic force of the lower connecting member 130 away from the lower coupling frame 22 is applied by the first spring 41, so that the upper connecting plates 118 and the lower connecting plates 114 of the lower telescopic body 11 are respectively away from each other. The elastic force away from the upper connecting member 131 is applied to the top frame 3 by the second spring 42, so that the upper connecting plates 127 and the lower connecting plates 124 of the upper telescopic body 12 are respectively away from each other. Thereby, the transformable toy 100 is in an extended state (shown in fig. 3) in which the top plate 126 and the bottom plate 113 are away from each other.

Referring to fig. 3 and 8, when a user intends to deform the transformable toy 100 from the expanded state to a contracted state, a downward pressure F is applied to the top surface of the top plate 310 of the top frame 3, so that the top frame 3 moves downward. In the process that the top frame 3 moves downwards, the top tray 310 drives the upper telescopic body 12 to move downwards and compress the upper telescopic body 12, so that the upper connecting plates 127 are respectively close to the lower connecting plates 124. Meanwhile, the upper telescopic body 12 drives the connecting unit 13 to move downward and compresses the lower telescopic body 11 through the connecting unit 13, so that the upper connecting plates 118 are respectively close to the lower connecting plates 114. On the other hand, the top plate 310 compresses the second spring 42 to be deformed by the top plate 126 and accumulates a return elastic force, and at the same time, the second spring 42 moves the link unit 13 downward and compresses the first spring 41 to be deformed by the link unit 13 and accumulates a return elastic force.

Then, the latching arm sections 228 of the lower latching hooks 221 of the bottom chassis 2 and the upper latching hooks 321 of the top chassis 3 penetrate into the channels 14. Then, each of the upper hooks 321 extends into between the corresponding lower hook 221 and the separating baffle 211. When the lower inclined surface 324 of the upper hook 323 of each upper hook 321 contacts and slides on the upper inclined surface 231 of the lower hook 230 of the corresponding lower hook 221, the force component applied to the upper inclined surface 231 by the lower inclined surface 324 causes the detent arm 226 to bend and deform relative to the cantilever 225 and accumulate a return spring force, and at the same time, the cantilever 225 is also bent and deformed relative to the annular plate 220 and accumulate a return spring force due to being pressed downward by the detent arm 226. Thereby, the latch arms 226 of the lower latches 221 are respectively expanded by the upper latches 321 to rotate in a first rotation direction R1 and a second rotation direction R2 opposite to the first rotation direction R1.

It should be noted that, by the design manner that the separation baffle 211 is spaced between the latch arms 226 of the lower latches 221, when the bottom end of any one of the upper latches 321 contacts the top end of the separation baffle 211 due to position deviation in the downward movement process of the top frame 3, the upper latch 321 is blocked by the separation baffle 211, so that the top frame 3 cannot move downward. Therefore, the upper hooks 321 are prevented from being subsequently unable to contact and be clamped on the lower hooks 221 respectively due to dislocation.

Referring to fig. 9, when the lower inclined surface 324 of the upper hook 323 of each upper hook 321 is separated from the corresponding upper inclined surface 231 of the lower hook 230, the lower hook 221 is reset by the restoring elastic force accumulated by the latch arm 226 and the cantilever 225, so that the latch arm 226 of the lower hook 221 rotates along the second rotation direction R2 and the first rotation direction R1, respectively. Therefore, each lower hook 221 can automatically return to a clamping position where the lower hook 230 is clamped at the top end of the corresponding upper hook 323. At this time, the transformable toy 100 is transformed to the contracted state and positioned in the contracted state.

In the present embodiment, the bottom chassis 2 is respectively engaged with the upper hooks 321 of the top chassis 3 by the lower hooks 221, so that the lower hooks 221 can play a role of limiting the upper hooks 321 to move upward along the vertical direction Z and also can play a role of limiting the upper hooks 321 to move laterally along the second horizontal direction Y at the same time when in the engaged position. Therefore, the retractable assembly 1 and the top frame 3 of the transformable toy 100 are not separated from the upper hooks 321 by the external force along the vertical direction Z or the external force along the second transverse direction Y, so that the transformable toy 100 can be stably positioned in the collapsed state.

Referring to fig. 3 and 10, when a user intends to transform transformable toy 100 from the contracted state to the expanded state, there are two modes of operation:

one of the modes of operation is in coordination with the play of the transformable toy 100:

first, the chassis 2 of the transformable toy 100 is oriented downward such that the tip end portion 232 of the force-receiving arm segment 229 of the lower hook 221 faces a floor 5. Subsequently, the transformable toy 100 is forcibly thrown toward the ground surface 5, and when the tip end portions 232 of the force-receiving arm sections 229 contact the ground surface 5, the reaction force of the ground surface 5 to the tip end portions 232 is to apply the upper pressure P to the respective tip end portions 232. When the tip 232 of each of the force-receiving arm segments 229 is pressed upward by the upper pressure P, the cantilever 225 is caused to bend upward relative to the annular plate 220 and accumulate a return spring force, so that the lower hook 221 rotates in the first rotation direction R1 and the second rotation direction R2, respectively.

When each of the lower hooks 221 rotates to a release position where the lower hook 230 is separated from the corresponding upper hook 323 of the upper hook 321, the upper connecting

plates

118 and 114 of the lower telescopic body 11 are separated from each other by the accumulated return elastic force of the first spring 41, and the upper connecting

plates

127 and 124 of the upper telescopic body 12 are separated from each other by the accumulated return elastic force of the second spring 42. Thereby, the transformable toy 100 generates a bouncing motion on the ground 5, and can smoothly and rapidly automatically return to the extended state shown in fig. 3.

Another operation mode is that the user operates the following steps:

when the user applies the upper pressure P to the tip portion 232 with his or her finger, the transformable toy 100 is automatically restored to the expanded state as described above when each of the lower hooks 221 is pivoted to the release position as described above. Furthermore, the user can also apply two opposite lateral pressures extending in the second transverse direction Y to the outer sides of the force-receiving arm sections 229 by using the fingers to rotate the latch arms 226 of the lower latches 221 relative to the suspension arms 225 in the first and second rotational directions R1 and R2, respectively. When each of the latch arms 226 is rotated to a position where the lower hook 230 is separated from the corresponding upper hook 323, the transformable toy 100 can be automatically restored to the expanded state in the above-described manner.

By the two operation modes, the use and operation flexibility of a user can be provided. In addition to enjoyment, the operation method according to the play of the transformable toy 100 can automatically release the lower hook 221 from the upper hook 321 without the user's own operation of the lower hook 221. In the way of self-operation by the user, no matter the upper pressure P is applied to the tip end 232 of the force-receiving arm segment 229 or the lateral pressure is applied to the outer side of the force-receiving arm segment 229, the user only needs to apply a force to the force-receiving arm segment 229 along a single direction to release the lower hooks 221 from the corresponding upper hooks 321, which is very simple and convenient in operation and can save the time consumed in the operation process.

In this embodiment, the design manner of each lower hook 221 that the first length L1 of the latching arm segment 228 is greater than the second length L2 of the force-receiving arm segment 229 enables the latching arm segment 228 to separate the lower hook 230 from the corresponding upper hook 323 only by a small rotation when the tip 232 of the force-receiving arm segment 229 is applied with the upper pressure P or when the lateral pressure is applied to the outer side of the force-receiving arm segment 229. Therefore, the clamping state between the lower clamping hook 221 and the corresponding upper clamping hook 321 can be rapidly released, and the convenience in use and operation is improved. By the design of the tip portion 232 of the stressed arm section 229, the tip portion 232 can achieve a stress concentration effect when bearing the upper pressure P, and further can rapidly transmit the upper pressure P to the cantilever 225 to facilitate bending deformation thereof.

It should be noted that, in other embodiments of the present embodiment, the number of the lower hooks 221 of the bottom chassis 2 and the number of the upper hooks 321 of the top chassis 3 can also be designed to be one according to requirements, and the number is not limited to the number disclosed in the present embodiment. In addition, the elastic member 4 may be provided with only the first spring 41 and the second spring 42 may be omitted as required. Furthermore, the number of the telescopic bodies of the telescopic assembly 1 may be one or three, in a state where the number of the telescopic bodies is one, the bottom frame 2 and the top frame 3 may be respectively disposed on a bottom plate and a top plate of the telescopic body, the connecting unit 13 may be omitted from the telescopic assembly 1, and the number of the springs of the elastic assembly 4 is one. In a state where the number of the telescopic bodies is three, the number of the connection units 13 of the telescopic assembly 1 and the number of the springs of the elastic assembly 4 need to be two, respectively.

In summary, in the transformable toy 100 according to the present embodiment, by designing the lower hooks 221 of the bottom frame 2 and the upper hooks 321 of the top frame 3, the lower hooks 221 can be automatically and respectively engaged with the upper hooks 321 by applying the lower pressure F to the top frame 3. In an operation mode in accordance with the play of the transformable toy 100, the lower hook 221 can be automatically released from the upper hook 321 by applying the upper pressure P to the tip portion 232 of the lower hook 221. In the self-operation mode, the user only needs to apply a force to the force-receiving arm 229 along a single direction to release the lower hook 221 from the upper hook 321, which is very simple and convenient in operation. Therefore, the convenience of operating the lower hook 221 and the upper hook 321 in the aspects of clamping and releasing can be provided. In addition, by the first spring 41 and the second spring 42 of the elastic component 4 and the connection manner between the telescopic component 1, the bottom frame 2 and the top frame 3, and the first spring 41 and the second spring 42 can respectively extend and contract along the vertical direction Z and are the same as the extending and contracting direction of the telescopic component 1, so that the first spring 41 and the second spring 42 can uniformly apply elastic force to the telescopic component 1 and smoothly bounce it open, so that the transformable toy 100 can be rapidly deformed to the stretching state, and the purpose of the utility model can be really achieved.

Claims

1. a transformable toy is characterized in that:

The transformable toy includes a telescopic component, a bottom frame, a top frame, and an elastic component. The telescopic component includes a bottom plate and a top plate opposite to the bottom plate. The telescopic component can be operated to expand and contract in an up-down direction. The bottom frame is disposed on the bottom plate and includes at least one lower hook, the top frame is disposed on the top plate and includes at least one upper hook that can be detachably clamped to the lower hook, and the elastic component is disposed on the inside the telescopic assembly and apply the elastic force to keep the top plate away from the bottom plate, the top frame can be applied with a downward pressure to make the upper hooks engage with the lower hooks, and the lower hooks can An upper pressure opposite to the downward pressure is applied to disengage the lower hooks from the upper hooks.

2 . The transformable toy according to claim 1 , wherein the lower hook has an upper slope facing upward, the upper hook has a lower slope facing downward, and the lower slope is used to contact the The upper inclined surface can be slid on it to promote the lower hook to be bent and deformed, so that the lower hook can be clamped to the upper hook.

3 . The transformable toy according to claim 1 , wherein the lower hook has a cantilever and a locking arm, and the locking arm is integrally connected to one end of the cantilever for locking the cantilever. 4 . The upper hook, the bottom end of the hook arm is used to bear the upper pressure to urge the cantilever to bend and deform, so as to drive the hook arm to separate from the upper hook.

4 . The transformable toy according to claim 3 , wherein the latching arm has a latching arm segment and a force-receiving arm segment, and the latching arm segment is integrally connected to one end of the cantilever and protrudes. 5 . The top surface of the cantilever extends out for clamping the upper hook, and the force-receiving arm section is formed at the bottom end of the clamping arm section and protrudes from the bottom surface of the cantilever to accept the pressure.

5 . The transformable toy according to claim 4 , wherein the first length of the latching arm segment taken along the up-down direction is greater than the first length of the force-receiving arm segment taken along the up-down direction. 6 . Two lengths.

6 . The transformable toy according to claim 4 , wherein the force-receiving arm segment has a tip portion located at the bottom end for receiving the upper pressure. 7 .

7 . The transformable toy according to claim 4 , wherein the locking arm segment has a lower hook portion adjacent to the top end, the lower hook portion has an upper slope facing upward, and the upper hook has The upper hook portion adjacent to the bottom end has a lower inclined surface facing downward, the lower inclined surface is used to contact the upper inclined surface and can slide on it to promote the clamping arm to bend and deform, so as to make the The lower hook portion can be clamped to the upper hook portion.

8. The transformable toy according to any one of claims 1 to 7, wherein the bottom frame comprises two lower hooks, the lower hooks are along a direction substantially perpendicular to the up-down direction The horizontal direction is reversed and spaced apart, the top frame includes two upper hooks, the upper hooks are reversely arranged along the horizontal direction and are spaced apart, and the upper hooks are respectively used for locking the lower hook.

9 . The transformable toy according to claim 8 , wherein the bottom frame further comprises a partition baffle spaced between the lower hooks, and the partition baffle is used to block the corresponding upper hooks. 10 . The hooks, each of the upper hooks is used to pass through between the corresponding lower hooks and the partition baffle.

10 . The transformable toy according to claim 8 , wherein the base frame comprises a base frame body and a lower joint frame body, the base frame body has a seat plate, and a plurality of protruding parts are arranged on the seat. 11 . The top surface of the board is provided with the hooks of the bottom plate, the seat plate is in contact with the bottom surface of the bottom plate and is formed with two perforations, and the lower joint frame has a top surface abutting against the bottom plate The annular plate is buckled by the hooks, and the lower hooks are connected to the annular plate, the lower hooks are respectively penetrated through the through holes and partially protrude from the bottom surface of the seat plate.

11 . The transformable toy according to claim 8 , wherein the top frame comprises a top frame body, and an upper combined frame body, the top frame body has a top plate, and two protrusions are arranged on the top frame. 12 . The hook on the bottom surface of the plate, the top plate abuts on the top surface of the top plate, the upper combination frame has a base post, and the upper hook protruding from the bottom end of the base post, the The base post is abutted against the bottom surface of the top plate, and the hook is fastened to the bottom end of the base post.

12 . The transformable toy according to claim 1 , wherein the elastic component comprises a spring arranged in the telescopic component and applying the elastic force to it, and the spring can expand and contract along the up-down direction. 13 . .

13 . The transformable toy according to claim 1 , wherein the telescopic assembly comprises a lower telescopic body, an upper telescopic body, and a connecting unit, and the lower telescopic body has the bottom plate and is located above the bottom plate. 14 . The upper board, the upper telescopic body has a lower board stacked on the top of the upper board, and the top board located above the lower board, and the connecting unit connects the upper board and the lower board Together and together with the upper plate and the lower plate, a channel is defined, the channel is used for the lower hook and the upper hook to pass through, and the elastic component comprises a channel disposed in the lower telescopic body The first spring is abutted between the bottom frame and the connecting unit and can be telescopically deformed along the up-down direction.

14. The transformable toy according to claim 13, wherein the bottom frame is formed with a lower positioning slot, the connecting unit is formed with an upper positioning slot, and the first spring The lower end portion in the lower positioning card slot, and the upper end portion locked in the upper positioning card slot.

15. The transformable toy according to claim 13, wherein the elastic component further comprises a second spring arranged in the upper telescopic body, the second spring abutting against the connecting unit and the The top plates can be telescopically deformed along the up-down direction.

16. The transformable toy according to claim 15, wherein the connecting unit is formed with a lower positioning slot, the top frame is formed with an upper positioning slot, and the second spring The lower end portion in the lower positioning card slot, and the upper end portion locked in the upper positioning card slot.