CN212881017U - Multi-monomer combined toy with variable posture - Google Patents

Abstract

The utility model discloses a multi-unit combined toy with variable postures, which belongs to the field of combined toys, and utilizes a supporting structure body that a toy unit can move relatively in the modeling of the toy unit to be detachably connected to another toy unit, thereby forming a toy combination body, realizing the utilization of the movable component of the toy unit, and not needing to specially arrange the movable component connection on the toy unit, achieving the purpose of combining the toy combination body through simple operation similar to plugging, and the toy combination body can flexibly and stably change the postures, and improving the interestingness of the combined toy; non-modeling components in the toy monomer are reduced, and the simulation degree of the toy monomer is improved; unstable connection caused by a detachable and movable connecting part is avoided; the toy is suitable for various toy units with various shapes, complex shapes and variable shapes, and is transformed into a toy combination body in a convenient mode.

Description

Multi-monomer combined toy with variable posture

Technical Field

The utility model relates to a combination toy field specifically is a many monomer combination toy of variable posture.

Background

In order to attract the eyes of consumers and cater to their preferences, there are more and more kinds of combination toys. The combined toy mainly comprises at least more than two single toys. The single toy is designed into a certain toy shape and has the fun of independent play, study, entertainment and the like. Meanwhile, each single toy can be combined into a combined toy with larger size through movable deformation or disassembling, assembling and the like, and the combined toy can be in a robot shape. The single toys are spliced into the combined toy, and the pleasure of playing can be increased, so that the combined toy is popular with consumers.

At present, the single toys are mainly a plurality of same type modeling, such as modeling of machines, vehicles, ships, characters, letters, numbers and the like. The shapes of the single toys are mainly similar to or can be transformed into the shapes of squares, bars and the like, so that the combined toy body with set shapes can be easily formed. However, this results in that the degree of restitution of the figure by the individual toy is reduced, and the figure having an irregular shape, particularly the figure of an animal or the like, cannot be referred to. If the toy figure is changed into a regular figure by adopting anthropomorphic design and the like, the design of the toy figure is unreal, and if the toy figure is highly simulated, the self-deformation and the combined toy figure are difficult to construct.

Particularly, the posture of the existing toy cannot be changed after the toy is combined, and a rotary connecting structure is required to be arranged at the connecting position between the single bodies, so that the posture can be changed after the toy is combined. The rotary connecting structures do not belong to the modeling part, and only corresponding structure hiding can be arranged or the simulation degree of the modeling can be influenced. In addition, the structure which can be disassembled by rotating connection is unstable, so that the toy monomer is easy to fall off. For the toy single bodies with irregular shapes, the combination mode of combining the toy bodies is more difficult to set, and the posture can be changed.

Disclosure of Invention

The utility model aims to provide a: the utility model provides a many monomers of variable posture make up toy to solve irregular shape toy monomer and be difficult to under the influence molding fidelity condition, through simple convenient combination operation, make up for can alternate the gesture, have the toy assembly of abundant enjoyment of playing.

In order to realize the purpose, the utility model discloses a technical scheme is:

a multi-monomer combined toy with variable postures comprises a plurality of deformable monomers, wherein each deformable monomer has a toy shape and can be deformed into a combined shape, each deformable monomer can be combined into an anthropomorphic combined body with a body and four limbs, at least one deformable monomer is provided with a movable structural member in rotary connection, and the movable structural member is detachably connected with the other deformable monomer, so that when the movable structural member moves relative to the deformable monomers, the relative positions of the two deformable monomers can be changed. It is understood that the movable structure may be a movable molding portion of the toy cell, such as a limb, a wheel, etc., and the movable structure is movably connected with respect to the toy cell, including but not limited to, the movable structure being rotatably connected with the toy cell via a rotating shaft, or the movable structure being slidably connected with the toy cell in a straight line, a curved line, or a combination thereof.

The multi-monomer combined toy with variable postures is preferably characterized in that the combined body comprises deformable monomers of a body, two lower limbs and two upper limbs; the deformation single bodies of the lower limbs are detachably connected to the two sides of the lower portion of each deformation single body respectively, and the deformation single bodies of the two upper limbs are detachably connected to the movable structural members on the two sides of each deformation single body respectively. The upper limb deformation single body can be swung to drive the body movable structural part to move relative to the body deformation single body, and the lower limb deformation single body can be swung to move relative to the body deformation single body to realize posture change. It is understood that the connection mode of the parts of the toy combination includes, but not limited to, the upper limb deformation unit and the lower limb deformation unit are respectively detachably connected to the four movable structural members in the body deformation unit; or the movable structural members in the upper limb deformation monomer and the lower limb deformation monomer are respectively detachably connected to the trunk deformation monomer, or the movable structural members in the trunk deformation monomer are connected.

Preferably, the transformable toy is an animal-shaped transformable toy, and the transformable individual of the lower limbs includes a body part and a body part which can be joined to form a complete body, the body part is movably connected to the body part, and the body part has a support surface so that the body part can support the standing of the transformable individual of the lower limbs after the transformable individual is transformed. Specifically, the body main body and the body split body are provided with a combined surface for supporting, and when the body split body moves, the combined surface of the body split body is separated and moves to the lower part of the combined body, so that the purpose of supporting the combined body is achieved.

Preferably, the multi-body combination toy with variable postures includes two body parts, two notches are respectively formed at both sides of the body part, and the body parts are movably connected to the notches of the body part in a corresponding manner. The two side body parts can be symmetrical relative to the body part, and the body part has the same supporting combined surface, so that the effect of stable support is achieved. The three-point support stabilizing effect can be achieved by arranging a third body part in front or back besides the body parts on the two sides without limitation.

In the above multi-cell combination toy with variable postures, it is preferable that a strip-shaped hole is provided in the rear part of the trunk body, a slide shaft which is slidably fitted is provided in the strip-shaped hole, and the trunk body is connected to the slide shaft so as to be connected to the trunk body in a translatable and rotatable manner. The translation is used for the separation of the combination surface in the body components of a whole that can function independently, and the body components of a whole that can function independently rotates towards the assembly below of being convenient for after the separation.

In the above multi-cell toy set with variable postures, it is preferable that the deformable cell of the upper limb has an animal shape and includes a body part and a body part which can be joined to form a complete body, and the body part is movably connected to the body part so that the deformable cell of the upper limb can form a shoulder of the set after being deformed. Including but not limited to, the body and the body are connected in a rotating and translating way, the translation provides space for rotation, the body can rotate a certain angle relative to the body, and the body is deformed from the toy shape to a combined shape which can be used as the upper limb shoulder of the combined toy body. In another embodiment, the body is connected to two body parts at one end via a universal shaft, so that the body parts are transformed from the toy figure to the combined shape of the upper limbs and the shoulders.

Preferably, the multi-cell toy set with variable postures further comprises a head deformable cell, wherein the deformable cell of the body has an animal shape and comprises a body main body and a body sub body which can be spliced into a complete body, and the body sub body is movably connected to the body main body, so that after the deformable cell of the body is deformed, the head deformable cell is detachably connected to a shielding part of the body main body by the body sub body. The deformable body of the head comprises a head body and a head body which is rotatably connected with the head body, a first plug hole is formed in the position, shielded by the head body, of the head body, a first plug column is arranged in the position, shielded by the body, of the body deformable body, and the first plug column is connected with the first plug hole in a matched mode. The deformed single body of the head part is provided with a second plug hole, the deformed single body of the body is provided with a second plug column, and the second plug column is connected with the second plug hole in a matched mode.

The multi-monomer combined toy with variable postures is preferably provided with two deformable monomers which can be connected with the combined body, wherein the movable structural member of one deformable monomer is provided with a connecting buckle column, the other deformable monomer is provided with a connecting hole, and the connecting buckle column is matched with the connecting hole so that the two deformable monomers can be fixedly connected in an inserting way. It will be appreciated that the connection may be varied, which may facilitate disassembly, and may be maintained fixed while the toy body is being repositioned, including, but not limited to, snap connections, threaded connections, etc.

The above multi-monomer combined toy with variable postures is preferably provided with an animal model, a vehicle model, an airplane model or a human shape; the combination body is combined by one or more than one type of deformed monomers. The above toy deformable monomer is shaped to have relatively movable members, such as legs and heads of animals, such as tires of vehicles, robot arms, such as wings of airplanes, propellers, and the like, such as human-shaped limbs, and the like, which can be used as movable structural members for connecting the deformable monomer to change the posture of the toy combination.

Preferably, each transformable single body is in a dinosaur shape, the transformable single body comprises a body and support legs rotatably connected to the body, and the movable structural members are support legs with connecting pieces. In the dinosaur shape, the head, the trunk and the tail are generally in a long strip shape, the head and the tail are sharp, the middle is wide, and the dinosaur shape is generally difficult to be used as a combined toy deformation single body. Meanwhile, the detachable connection of the dinosaur supporting legs and the body of another dinosaur can be utilized to realize the posture deformation of the toy combination body.

Compared with the prior art, the utility model, have following advantage:

(1) the utility model utilizes the movable construction member which can relatively move in the shape of the deformation monomer and can be detachably connected to another deformation monomer, thereby forming a toy assembly, realizing the utilization of the movable construction member of the deformation monomer, and not needing to specially set a rotary connecting piece, achieving the purpose of combining the toy assembly through simple operation similar to plugging, and the assembly can flexibly and stably change the posture, and improving the interest of the combined toy; non-modeling components in the toy deformation single body are reduced, and the simulation degree of the toy deformation single body is improved; unstable connection caused by a detachable and movable connecting part is avoided; the toy deformation unit is suitable for various toy deformation units with various shapes, complex shapes and variable shapes, and is transformed into a toy combination body in a convenient mode.

(2) The utility model is suitable for splicing the dinosaur-shaped deformable single bodies with narrow heads and tails into the combined toy body of the robot; the dinosaur-shaped lower limb deformation single body can be movably deformed to form a structure capable of supporting the toy combination body to stand; the dinosaur-shaped upper limb toy deformation monomer can be movably deformed to form the shoulder on the robot artificial upper limb; the toy combination can support the combination of six dinosaur-shaped deformable monomers of the head, the body and the four limbs. The simulation degree of the deformation monomer is high, the posture can be changed, the combination body is attached to the human shape and can also be adjusted, the operation of posture changing and combination is simple, the playing method is various, and the interest degree is high.

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

Drawings

FIG. 1 is a schematic diagram of a front view of an exploded structure of a toy assembly of the present invention;

FIG. 2 is a schematic view of a posture-changing three-dimensional structure of the toy assembly of the present invention;

FIG. 3a is a schematic view of the exploded structure of the body deformation unit in the assembled state;

fig. 3b is a schematic three-dimensional structure of the body deformation unit of the present invention in the shape;

FIG. 4a is a schematic view of the exploded structure of the left lower limb deformation unit in the assembled state;

fig. 4b is a schematic three-dimensional structure diagram of the left lower limb deformation unit of the present invention in the shape;

FIG. 5a is a schematic view of the explosion structure of the right lower limb deformable unit of the present invention in the assembled state;

fig. 5b is a schematic three-dimensional structure view of the right lower limb deformation unit of the present invention in a modeling form;

FIG. 6a is a schematic view of the explosion structure of the left upper limb deformation unit in the assembled state;

fig. 6b is a schematic view of the three-dimensional structure of the left upper limb deformation unit in the shape of the utility model;

FIG. 7a is a schematic view of the explosion structure of the right upper limb deformable monomer in the assembled state;

fig. 7b is a schematic view of the three-dimensional structure of the right upper limb deformation unit of the present invention in the shape;

fig. 8a is a schematic view of the exploded structure of the head deformable unit of the present invention in the assembled state;

fig. 8b is a schematic perspective view of the head deformation unit of the present invention in a modeling form.

Reference numerals: the body deformation single body 1, the left lower limb deformation single body 2, the right lower limb deformation single body 3, the left upper limb deformation single body 4, the right upper limb deformation single body 5, the head deformation single body 6, the movable structural member 7, the connecting buckle column 71, the connecting hole 72, the first body main body 11, the first front supporting leg 12, the first rear supporting leg 13, the first head 14 and the first tail body part 15; a second body main body 21, a second front leg 22, a second rear leg 23, a second head 24, a second tail body part 25, a second back part 26; a third torso body 31, a third front leg 32, a third rear leg 33, and a third head 34. A third tail body division 35, a third back division 36; a fourth torso body 41, a fourth front leg 42, a fourth rear leg 43, and a fourth head 44. A fourth tail body 45; a fifth torso body 51, a fifth front leg 52, a fifth rear leg 53, a fifth head 54, a fifth tail body 55; a sixth body portion 61, sixth legs 62, a sixth head 63, a sixth shoulder portion 64, and a sixth body portion 65.

Detailed Description

As shown in fig. 1 to 8, the present invention discloses a transformable multi-deformable-body combined toy, which comprises six body transformable units 1, left lower limb transformable unit 2, right lower limb transformable unit 3, left upper limb transformable unit 4, right upper limb transformable unit 5 and head transformable unit 6, each of which is composed of different dinosaurs, wherein each of the toy transformable units is transformable from dinosaurs (see fig. 3b, 4b, 5b, 6b, 7b, 8b) into a combined form of body form (see fig. 3a), left lower limb form (see fig. 4a), right lower limb form (see fig. 5a), left upper limb form (see fig. 6a), right lower limb form (see fig. 7a) and head form (see fig. 8a), when the combined form is adopted, the left and right lower limb transformable units are connected to both sides of the lower part of the body transformable unit 1, the left and right upper limb transformable units are connected to both sides of the upper part of the body transformable unit 1, the head deformable units 6 are connected to the upper ends of the trunk deformable units 1 to form a toy assembly in a human shape (see fig. 1).

The body deformation single body 1, the left lower limb deformation single body 2, the right lower limb deformation single body 3, the left upper limb deformation single body 4, the right upper limb deformation single body 5 and the head deformation single body 6 respectively comprise a head part, a body part, supporting legs, a tail part and other modeling structural bodies, wherein the supporting legs are relatively movable structural members in the toy modeling of the toy deformation single body, and the movable structural members 7 are formed by arranging connecting buckling columns 71. The movable structural member 7 is rotatably and movably connected with the corresponding toy deforming monomer. In the combined form, the two side legs of the body deformation unit 1 are provided with connecting buckles 71, the lower side of the body deformation unit 1 is provided with two connecting holes 72, one of the legs of the left lower limb deformation unit 2 and the right lower limb deformation unit 3 is provided with the connecting buckles 71, and the bodies of the left upper limb deformation unit 4 and the right upper limb deformation unit 5 are provided with the connecting holes 72. Two connecting buckles 71 of the left lower limb deformation single body 2 and the right lower limb deformation single body 3 are respectively inserted and fixedly connected to the lower side of the body deformation single body 1, and two connecting holes 72 of the left upper limb deformation single body 4 and the right upper limb deformation single body 5 are respectively inserted and fixedly connected to connecting buckles 71 of two side supporting legs of the body deformation single body 1. The corresponding connecting button posts 71 and the connecting holes 72 are matched, inserted, fixedly connected and detachably connected.

Referring to fig. 3a and 3b, the trunk deformation unit 1 is in a shape of a tyrannosaurus toy, and includes a first trunk body 11, first front legs 12 connected to both sides of the front portion of the first trunk body 11 through a rotation shaft, first rear legs 13 connected to both sides of the rear portion of the first trunk body 11 through a rotation shaft, a first tail trunk body 15 rotatably connected to the rear end of the first trunk body 11 through a connection rod, and a first head 14 connected to the front end of the first trunk body 11 through a rotation shaft. The outer side of one of the first rear supporting legs 13 is respectively provided with a connecting buckle column 71 which is used for being connected with the left upper limb deformation unit 4 in an inserting way and is the movable structural member 7 by the upper limb deformation unit. The upper end of the first head part 14 is respectively provided with a connecting hole 72 which is respectively used for being connected with the left lower limb deformation single body 2 and the right lower limb deformation single body 3 in an inserting way. The first tail body part 15 is the body movable structural member 7 of the body deformation unit 1, and the first tail body part 15 can shield a boss arranged on the first body 11 and can be fixedly connected with the head deformation unit 6. Two uprights at the front side of the first torso part 11 are used to connect the head part moving structures 7 of the head part deforming unit 6. In the assembled state, the first head part 14 of the trunk deformation unit 1 faces downward, and the first tail trunk part 15 turns back along with the link to expose the boss.

Referring to fig. 4a and 4b, the left lower limb deformation unit 2 is in a shape of a dinosaur toy with a dorsal scale, and includes a second body 21, a second front leg 22 connected to both sides of the front portion of the second body 21 by a rotation shaft, a second rear leg 23 provided at the rear portion of the second body 21, and a second head 24 connected to the front portion of the second body 21 by a rotation shaft. Two sides of the rear part of the second body main body 21 are respectively provided with second tail body parts 25, and the two second tail body parts 25 and the rear part of the second body main body 21 jointly form a tail shape of the left lower limb deformation unit 2. The rear part of the second body main body 21 is provided with a second track hole, and a rotating shaft on the left second rear leg 23 sequentially passes through the left second tail body part 25, the second track hole, the right second tail body part 25 and is connected with a rotating shaft on the right second rear leg 23. The second track hole is strip-shaped, and two ends of the second track hole are provided with limiting bosses. The second tail body parts 25 on both sides are regular polygon holes, and are in interference fit with the rotating shaft cylinders on the second rear supporting legs 23, so that the second tail body parts 25 can be prevented from rotating. A second back part body 26 is hinged to the rear side of the rear part of the second body main body 21. The second back split body 26 and the second tail body split bodies 25 on the two sides are the lower limb movable structural member 7. The second tail body part 25 and the second body part 21 have a plane dividing surface, and can translate and rotate downwards along the second track hole, so that the dividing surface faces downwards for support. The second back section 26 can be pivoted downwardly along the hinge for support. The second front leg 22 on the right side is provided with the connecting buckle column 71 to be connected with the body deformation single body 1 in a plugging mode, and is the movable structural member 7.

Referring to fig. 5a and 5b, the right lower limb deformation unit 3 is in the shape of a xiphophora dinosaur toy, and includes a third body 31, third front legs 32 connected to both sides of the front portion of the third body 31 by a rotation shaft, third rear legs 33 provided at the rear portion of the third body 31, and a third head 34 connected to the front portion of the third body 31 by a rotation shaft. Third tail body parts 35 are respectively arranged on two sides of the rear part of the third body main body 31, and the two third tail body parts 35 and the rear part of the third body main body 31 jointly form a tail shape of the right lower limb deformation single body 3. The rear part of the third body main body 31 is provided with a third track hole, and the rotating shaft on the left third rear leg 33 sequentially passes through the left third tail body 35, the third track hole, the right third tail body 35 and is connected with the rotating shaft on the right third rear leg 33. The third track hole is strip-shaped, and two ends of the third track hole are provided with limit bosses. The third tail body parts 35 on both sides are regular polygon holes, and are in interference fit with the rotating shaft cylinders on the third rear supporting legs 33, so that the third tail body parts 35 can be prevented from rotating. The front part of the third body main body 31 is hinged with a third back split body 36 through a connecting rod. The third back split body 36 and the third tail body split bodies 35 on the two sides are the lower limb movable structural member 7. The third tail body part 35 and the third body part 31 have a plane dividing surface, and can translate and rotate downwards along the third track hole, so that the dividing surface faces downwards for support. The third back sub-body 36 can be flipped down along the link hinge for support. The third front leg 32 on the left side is provided with the connecting buckle 71 to be connected with the body deformation unit 1 in a plugging manner, and is the movable structural member 7.

Referring to fig. 6a and 6b, the left upper limb deformation unit 4 is in the shape of a sub-saurolophus dinosaur toy, and includes a fourth body 41, fourth front legs 42 connected to both sides of the front portion of the fourth body by a rotation shaft, fourth rear legs 43 provided at the rear portion of the fourth body 41, and a fourth head 44 connected to the front portion of the fourth body 41 by a rotation shaft. The two sides of the rear part of the fourth body 41 are respectively provided with a fourth tail body 45, and the two fourth tail body 45 and the rear part of the fourth body 41 jointly form a tail shape of the right lower limb deformation unit 3. A fourth track hole is formed in the rear portion of the fourth body 41, and a rotating shaft of the left fourth rear leg 43 sequentially penetrates through the left fourth tail body 45, the fourth track hole, the right fourth tail body 45 and is connected with a rotating shaft of the right fourth rear leg 43. The fourth track hole is strip-shaped, and two ends of the fourth track hole are provided with limiting bosses. The fourth trunk body parts 45 on both sides are regular polygonal holes and are in interference fit with the rotating shaft cylinder on the fourth rear supporting leg 43, so that the fourth trunk body parts 45 can be blocked and rotated to form an outward turning shoulder shape at a set angle relative to the rotation of the fourth trunk body 41, and the fourth trunk body parts 45 on the left side and the right side can be buckled and connected into a whole at the tail end. The left and right fourth tail body parts 45 are the upper limb movement structural members 7. The connecting hole 72 is provided at the chest and abdomen of the fourth body main body 41 to be connected to the body deformable unit 1 by insertion.

Referring to fig. 7a and 7b, the right upper limb deformation unit 5 is in a shape of a triangle dragon dinosaur toy, and includes a fifth body 51, fifth front legs 52 pivotally connected to both sides of the front portion of the fifth body, fifth rear legs 53 pivotally connected to both sides of the rear portion of the fifth body 51, and a fifth head 54 pivotally connected to the front portion of the fifth body 51. Fifth tail body parts 55 are respectively arranged on two sides of the rear part of the fifth body main body 51, and the two fifth tail body parts 55 and the rear part of the fifth body main body 51 jointly form a tail shape of the right lower limb deformation unit 3. The rear part of the fifth body 51 is provided with a ball axle hole, and the fifth body 55 is provided with a ball axle which is matched with the ball axle hole so that the fifth body 55 can be turned outwards relatively to be in the shape of a shoulder. The fifth tail body parts 55 at the left and right sides can be connected into a whole at the tail end in a buckling way. The fifth right and left tail body parts 55 are the upper limb movement structural members 7. The fifth body 51 is provided with the connection hole 72 at the chest and abdomen to be connected with the body deformation unit 1 by plugging.

Referring to fig. 8a and 8b, the head-deforming unit 6 is in the shape of a pterosaur dinosaur toy, and includes a sixth trunk body 61, four sixth legs 62 pivotally connected to the front and rear sides of the sixth trunk body 61, respectively, a sixth shoulder part 64 translationally and rotatably connected to the sixth trunk body 61, and a sixth head 63 hinged to the sixth shoulder part 64. A sixth body section 65 is hinged to the front side of the sixth body section 61. The hidden part of the sixth body 61 is provided with a groove structure which is matched, inserted and connected with the lug boss on the first body 11. The sixth body part 65 is provided with a two-hole structure, which is connected to the pillar of the first body part 11 by plugging. The sixth body part 65 is the head movement structure 7.

The playing method of the utility model can be that: the body deformation single body 1, the left lower limb deformation single body 2, the right lower limb deformation single body 3, the left upper limb deformation single body 4, the right lower limb deformation single body 3 and the head deformation single body 6 have respective toy shapes, and the head, the front supporting leg and the rear supporting leg can be arranged into various postures. When combined, the trunk deformation unit 1, the left lower limb deformation unit 2, the right lower limb deformation unit 3, the left upper limb deformation unit 4, the right upper limb deformation unit 5 and the head deformation unit 6 can be deformed into a combined form. Specifically, in the body deformation unit 1, the first tail body part 15 is turned backwards, and the first head part 14 is prevented from being downward; in the left lower limb deformation single body 2, the second tail body split bodies 25 on the two sides are translated and rotated for 180 degrees, so that the splitting plane faces downwards, and the second back split body 26 in the middle is turned downwards; in the right lower limb deformation single body 3, the third tail body split bodies 35 on the two sides are translated and rotated for 180 degrees, so that the splitting plane faces downwards, and the third back split body 36 in the middle is turned downwards; in the left upper limb deformation monomer 4, the fourth tail body part is turned outwards; in the right upper limb deformation monomer 5, the two fifth tail body parts 55 are separated and turned outwards; in the head deforming unit 6, the sixth body part 65 is turned up to expose the inner groove structure, and the sixth shoulder part 64 is rotated and translated outward. Then, connecting the left lower limb deformation unit 2 with the buckle column 71 from the second front leg 22, and inserting the buckle column into the connecting hole 72 on the first head part 14 in the body deformation unit 1; connecting the right lower limb deformation unit 3 with a buckle column 71 from the third front leg 32 and inserting the right lower limb deformation unit into a connecting hole 72 on the first head 14 in the body deformation unit 1; the left upper limb deformation single body 4 is inserted into the connecting buckle 71 of the left first rear supporting leg 13 in the body deformation single body 1 from the connecting hole 72 on the fourth body main body 41; the right upper limb deformation single body 5 is inserted into the connecting buckle 71 of the right first rear supporting leg 13 in the body deformation single body 1 from the connecting hole 72 on the fifth body main body 51; the groove structure of the sixth body 61 of the head deformable unit 6 is inserted into the exposed boss of the first body 11 on the upper part of the body deformable unit 1, and the hole structure of the sixth body 65 of the head deformable unit 6 is inserted into the pillar on the first body 11 of the body deformable unit 1. And then, splicing the toy combination body.

Referring to fig. 2, in the toy combination, the left lower limb deformation unit 2 is swung to rotate the second body main body 21 relative to the second front leg 22, and the second front leg 22 is fixed relative to the body deformation unit 1, so that the posture of the left lower limb deformation unit 2 relative to the body deformation unit 1 is adjusted; the right lower limb deformation unit 3 is swung to enable the third body main body 31 to rotate relative to the third front support leg 32, the third front support leg 32 is fixed relative to the body deformation unit 1, and the posture of the right lower limb deformation unit 3 relative to the body deformation unit 1 is adjusted; swinging the left upper limb deformation single body 4 to drive the first rear support leg 13 on the body deformation single body 1 to rotate relative to the first body main body 11, so that the posture of the left upper limb deformation single body 4 relative to the body deformation single body 1 is adjusted; the right upper limb deformation single body 5 is swung to drive the first rear support leg 13 on the body deformation single body 1 to rotate relative to the first body 11, so that the posture of the right upper limb deformation single body 5 relative to the body deformation single body 1 is adjusted.

While the foregoing is directed to the preferred embodiment of the present invention, other and further modifications of the disclosed embodiment, as may be readily devised by those skilled in the art, may be made without departing from the spirit and scope of the present invention as defined by the appended claims.

Claims (10)

1. A multi-monomer combined toy with a variable posture comprises a plurality of deformable monomers (1-6), wherein the deformable monomers (1-6) have toy shapes and can be deformed into combined shapes, and each deformable monomer (1-6) can be combined into a human-shaped combined body with a body and four limbs, and the toy is characterized in that at least one deformable monomer (1-6) is rotatably connected with a movable structural member (7), and the movable structural member (7) is detachably connected with the other deformable monomer (1-6) so that when the movable structural member (7) moves relative to the deformable monomer (1-6), the relative positions of the two deformable monomers (1-6) can be changed.

2. A multi-cell posable toy set according to claim 1, wherein the assembly comprises deformable cells (1-6) of the body, the two lower limbs and the two upper limbs; the movable structural members (7) of the deformable single bodies (1-6) of the lower limbs are detachably connected to the two sides of the lower parts of the deformable single bodies (1-6) of the body respectively, and the deformable single bodies (1-6) of the two upper limbs are detachably connected to the movable structural members (7) of the two sides of the deformable single bodies (1-6) of the body respectively.

3. The multi-unit variable-posture assembly toy of claim 1, wherein the deformable unit (1-6) of the lower limb has an animal shape including a body part and a body part which can be joined to form a complete body, the body part being movably connected to the body part, the body part having a support surface so that the body part can support the standing of the assembly after the deformable unit (1-6) of the lower limb is deformed.

4. The reconfigurable assembly toy according to claim 3, wherein the number of the body sections is two, two notches are provided on both sides of the body section, and the body section is movably connected to the notches of the body section.

5. The multi-unit reconfigurable toy set according to claim 3, wherein a strip-shaped hole is provided in a rear portion of the body main body, a slide shaft that is slidably fitted is provided in the strip-shaped hole, and the body main body is connected to the slide shaft so that the body main body is connected to the body main body in a translatable and rotatable manner.

6. A multi-cell toy set with variable postures according to claim 1, characterised in that said deformable cells (1-6) of the upper limbs are shaped like an animal, comprising a body part and a trunk part which can be split into a complete body, said body part being movably connected to the body part so that after deformation of said deformable cells (1-6) of the upper limbs, the shoulders of the set can be formed.

7. The multi-unit variable-posture combination toy as claimed in claim 1, wherein the combination further comprises a head deformable unit (1-6), the deformable unit (1-6) of the body is an animal model comprising a body part and a body part which can be split into a complete body, the body part is movably connected to the body part, so that after the deformable unit (1-6) of the body is deformed, the head deformable unit (1-6) is detachably connected to the body part at the position where the body part shields the body part.

8. A multi-cell toy set with variable postures as claimed in claim 1, wherein the movable structural member (7) of one of the two deformable cells (1-6) connected to the combination is provided with a connecting button post (71), the other deformable cell (1-6) is provided with a connecting hole (72), and the connecting button post (71) and the connecting hole (72) are mutually matched to enable the two deformable cells (1-6) to be fixedly connected in an inserting way.

9. A posable multi-cell combination toy according to any of claims 1-8, wherein the morphable cells (1-6) are animal shaped, or vehicle shaped, or airplane shaped, or humanoid shaped; the combination body is combined by one or more than one type of deformation monomers (1-6).

10. A multi-cell reconfigurable toy set according to any of claims 1 to 8, characterized in that each of the reconfigurable cells (1-6) is of a dinosaur configuration, the reconfigurable cells (1-6) include a body and legs pivotally connected to the body, and the movable configurations (7) are legs with links.

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