CN111559673B - Receive traditional thread binding putting and concatenation building blocks suitable for concatenation building blocks - Google Patents

Abstract

The invention provides a take-up and pull-out device suitable for splicing building blocks and the splicing building blocks, which comprise: building block components, stay wire components; the building element comprises: a first building element, a second building element; the first building element comprises: a rotating assembly (2); the wire drawing member includes: a pull wire; the pull wire is wound on the rotating assembly (2); the second building element comprises: rotating the limiting assembly; the rotating assembly (2) is connected with the rotating limiting assembly; the rotating assembly (2) can rotate circularly around a central line formed by the rotating limiting assembly. The split-type building block is reasonable in structure and convenient to use, and can be well suitable for split-type building blocks, particularly large-particle split-type building blocks.

Description

Receive traditional thread binding putting and concatenation building blocks suitable for concatenation building blocks

Technical Field

The invention relates to the field of splicing building blocks, in particular to a take-up and pull-out device suitable for splicing building blocks and the splicing building blocks, and particularly relates to a take-up and pull-out device suitable for splicing large-particle building blocks.

Background

The splicing building blocks build a world for children, the imagination and creativity of the children are aroused, and the technical field of the splicing building blocks is dedicated to providing more 'creation materials' for the children, wherein the 'creation materials' are tiles for creating the world for the children. The following dilemma is faced in the field of traditional splicing building blocks: the splicing building blocks are small in splicing components, and can be spliced into more shapes, so that swallowing danger of children is easily caused; the splicing building blocks adopt larger splicing assemblies, and more types of splicing assemblies need to be designed. For child safety and ease when splicing the building blocks by children, the spliced building blocks are more biased towards the development of large-particle spliced building block assemblies. In the research and development of large granule concatenation building blocks subassembly, large granule concatenation building blocks subassembly uses the pivot inevitable. However, the large-sized spliced building blocks may pose a danger to children in the game if conventional metal hinges are developed using general mechanical principles. When the splicing building blocks are used abnormally by children, the children often fall, lose and bite the splicing building blocks, and the metal rotating shafts (such as the metal short sticks) are exposed, so that the danger is brought to the life safety of the children. There is a need in the art for a take-up and pull-up device that is well adapted to splicing building blocks (especially large-sized splicing building blocks) without using a conventional rotating shaft.

Patent document CN203820196U discloses a vertical automatic wire retracting structure and a charging pile, wherein the automatic wire retracting structure comprises a vertically placed strip-shaped frame, the inner end of the strip-shaped frame is fixedly arranged, and the outer end of the strip-shaped frame extends outwards; the strip-shaped frame is movably connected with a moving frame, the moving frame is connected with a rotating disc used for winding electric wires, and a driving mechanism used for driving the moving frame to move along the strip-shaped frame is arranged between the moving frame and the strip-shaped frame. The take-up guy wire structure in this patent is not well suited for use in splicing building blocks (especially large-grained splicing building blocks).

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a take-up and pull-out device suitable for splicing building blocks and the splicing building blocks.

According to the invention, the wire take-up and pull device suitable for splicing building blocks comprises: building block components, stay wire components; the building element comprises: a first building element, a second building element; the first block includes: a rotating assembly 2; the wire drawing member includes: a pull wire; the pull wire is wound on the rotating assembly 2; the second building element comprises: rotating the limiting assembly; the rotating assembly 2 is connected with the rotating limiting assembly; the rotating assembly 2 can rotate circularly around a central line formed by the rotating limiting assembly.

Preferably, the first block includes: a thumb wheel assembly 3; the thumb wheel assembly 3 is arranged at one end of the rotating assembly 2; the thumb wheel assembly 3 can rotate circumferentially around a central line formed by the rotation limiting assembly.

Preferably, the rotating assembly 2 comprises: a wire take-up groove 203; the wire take-up groove is formed in the middle of the rotating assembly 2; the pull wire is wound around the take-up groove 203.

Preferably, the rotating assembly 2 comprises: a threading hole 204; the threading hole 204 is arranged in the middle of the rotating assembly 2; the pull wire passes through the threading hole 204.

Preferably, the rotating assembly 2 comprises: a click slot 202; the click groove 202 is provided on an end surface of one end of the rotating member 2.

Preferably, the second building element comprises: a frame assembly 1; the frame assembly 1 includes: a female member, a male member; the rotation limiting assembly is arranged on the inner concave surface of the concave component.

Preferably, the frame assembly 1 comprises: a rotation axis bump 102; the rotating assembly 2 comprises: a rotating shaft boss groove 205; the rotating shaft salient point groove 205 is matched with the rotating shaft salient point 102; the rotating shaft salient point 102 is arranged on the inner concave surface of the concave component; the rotating shaft boss groove 205 is provided on the end surface of the other end of the rotating assembly 2.

Preferably, the rotating assembly 2 comprises: an elastic arm member 201; the elastic arm member 201 is arranged on the end face of one end of the rotating assembly 2; the elastic arm member 201 is disposed adjacent to the click slot 202. The elastic arm component of the rotating assembly is in rotating fit with the rotating shaft salient point on the frame, and the elastic arm component deforms to generate elasticity and prevent falling. The elastic arm component is similar to a tongue shape, a gap is reserved between the elastic arm component and the periphery, and a concave platform is arranged on the elastic arm component and can prevent the salient point of the rotating shaft from being separated.

Preferably, the number of the checkpoint slots 202 is multiple; the plurality of click grooves 202 are circumferentially arranged on the end face of one end of the rotating assembly 2; the frame assembly 1 further comprises: damping bumps 101; the damping bump 101 is matched with the clamping point groove 202. The rotating shaft convex point groove is in rotating fit with the rotating shaft convex point, and the damping convex point is in damping fit with the rotating shaft convex point groove of the rotating part, so that a click-click damping rotating effect is achieved.

Preferably, the method further comprises the following steps: a rotary connector 104 and a connecting female head; the rotary joint 104 is arranged on the male member; the female connecting head is arranged on one outer side face of the concave component; the second building element comprises: a frame rear rotating member 4; the frame rear rotating member 4 is disposed in the middle of the male member.

And (3) a wire drawing process: knotting after a line penetrates through the holes, then rotating the winding on the winding groove by the manual thumb wheel, and after the winding is finished, pulling the other end of the line to drive the rotating assembly to quickly pay off the line to form a playing method for winding and unwinding the line.

Compared with the prior art, the invention has the following beneficial effects:

1. the invention has reasonable structure and convenient use, and can be well suitable for splicing building blocks, in particular large-particle spliced building blocks;

2. in the invention, the elastic arm structure of the rotating assembly is in rotating fit with the rotating shaft salient point on the frame assembly, and the elastic arm structure deforms to generate elasticity and prevent falling. The elastic arm structure is similar to a tongue shape, a gap is reserved between the elastic arm structure and the periphery of the elastic arm structure, and a concave platform is arranged on the elastic arm structure and can prevent the salient point of the rotating shaft from being separated;

3. according to the invention, the rotating shaft salient point groove is in rotating fit with the rotating shaft salient point, and the damping salient point is in damping fit with the rotating shaft salient point groove of the rotating part, so that a clicking and clicking damping rotating effect is realized, and the pleasure of splicing the building blocks in use is better increased.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

fig. 1 is an exploded view of the overall structure of the present invention.

Fig. 2 is a schematic view of the overall structure of the present invention.

Fig. 3 is a schematic end view of a rotating assembly in an embodiment of the present invention.

Fig. 4 is another end view of the rotating assembly in an embodiment of the present invention.

Fig. 5 is a schematic view of a first transverse overall structure of the rotating assembly in the embodiment of the invention.

Fig. 6 is a second transverse overall structure diagram of the rotating assembly in the embodiment of the invention.

FIG. 7 is a schematic view of a frame assembly in an embodiment of the invention.

In the figure:

frame assembly 1 bayonet slot 202

Damping bump 101 wire collecting groove 203

Rotating shaft salient point 102 threading hole 204

Connecting female head 103 rotating shaft cam groove 205

Rotating connector 104 thumb wheel assembly 3

Rear rotating member 4 of rotating assembly 2 frame

Elastic arm member 201

Detailed Description

The present invention will be described in detail with reference to specific examples. The following examples will assist those skilled in the art in further understanding the invention, but are not intended to limit the invention in any way. It should be noted that it would be obvious to those skilled in the art that various changes and modifications can be made without departing from the spirit of the invention. All falling within the scope of the present invention.

As shown in fig. 1 to 7, the invention provides a take-up and pull-out device suitable for splicing building blocks, comprising: building block components, stay wire components; the building element comprises: a first building element, a second building element; the first block includes: a rotating assembly 2; the wire drawing member includes: a pull wire; the pull wire is wound on the rotating assembly 2; the second building element comprises: rotating the limiting assembly; the rotating assembly 2 is connected with the rotating limiting assembly; the rotating assembly 2 can rotate circularly around a central line formed by the rotating limiting assembly. Specifically, in one embodiment, the pull wire may be a plastic leather rope, a rubber rope, or a cotton rope.

Preferably, the first block includes: a thumb wheel assembly 3; the thumb wheel assembly 3 is arranged at one end of the rotating assembly 2; the thumb wheel assembly 3 can rotate circumferentially around a central line formed by the rotation limiting assembly.

Preferably, the rotating assembly 2 comprises: a wire take-up groove 203; the wire take-up groove is formed in the middle of the rotating assembly 2; the pull wire is wound around the take-up groove 203.

Preferably, the rotating assembly 2 comprises: a threading hole 204; the threading hole 204 is arranged in the middle of the rotating assembly 2; the pull wire passes through the threading hole 204.

Preferably, the rotating assembly 2 comprises: a click slot 202; the click groove 202 is provided on an end surface of one end of the rotating member 2.

Preferably, the second building element comprises: a frame assembly 1; the frame assembly 1 includes: a female member, a male member; the rotation limiting assembly is arranged on the inner concave surface of the concave component.

Preferably, the frame assembly 1 comprises: a rotation axis bump 102; the rotating assembly 2 comprises: a rotating shaft boss groove 205; the rotating shaft salient point groove 205 is matched with the rotating shaft salient point 102; the rotating shaft salient point 102 is arranged on the inner concave surface of the concave component; the rotating shaft boss groove 205 is provided on the end surface of the other end of the rotating assembly 2.

Preferably, the rotating assembly 2 comprises: an elastic arm member 201; the elastic arm member 201 is arranged on the end face of one end of the rotating assembly 2; the elastic arm member 201 is disposed adjacent to the click slot 202. The elastic arm component of the rotating assembly is in rotating fit with the rotating shaft salient point on the frame, and the elastic arm component deforms to generate elasticity and prevent falling. The elastic arm component is similar to a tongue shape, a gap is reserved between the elastic arm component and the periphery, and a concave platform is arranged on the elastic arm component and can prevent the salient point of the rotating shaft from being separated.

Preferably, the number of the checkpoint slots 202 is multiple; the plurality of click grooves 202 are circumferentially arranged on the end face of one end of the rotating assembly 2; the frame assembly 1 further comprises: damping bumps 101; the damping bump 101 is matched with the clamping point groove 202. The rotating shaft convex point groove is in rotating fit with the rotating shaft convex point, and the damping convex point is in damping fit with the rotating shaft convex point groove of the rotating part, so that a click-click damping rotating effect is achieved. The frame assembly 1 includes: a rotary connector 104 and a connecting female head 103; the rotary joint 104 is arranged on the male member; the female connection head 103 is arranged on one outer side face of the female member; the second building element comprises: a frame rear rotating member 4; the frame rear rotating member 4 is disposed in the middle of the male member.

And (3) a wire drawing process: knotting after a line penetrates through the holes, then rotating the winding on the winding groove by the manual thumb wheel, and after the winding is finished, pulling the other end of the line to drive the rotating assembly to quickly pay off the line to form a playing method for winding and unwinding the line.

Specifically, in one embodiment, the frame assembly 1 is connected to the bottom plate block through the rotary connector 104, the bottom plate block may be a bottom plate block of a toy vehicle splicing block, the frame assembly 1 is connected to another spotlight block through a connecting female head, and when a player uses a take-up and pull-off device suitable for splicing blocks to perform a take-up and pull-off operation, the player can also start a switch button of the spotlight block, so that a playing method that the take-up and pull-off operation is accompanied by light ray flicker is realized.

In another embodiment, the frame assembly 1 is connected with the bottom plate building block through the rotary connector 104, the frame assembly 1 is connected with another sound building block through the connecting female head, and when a player uses the pull-in and pull-out device suitable for splicing the building blocks to perform pull-in and pull-out operations, the player can also start the switch buttons of the sound building blocks to realize playing methods of the pull-in and pull-out operations along with sound effects.

Specifically, in one embodiment, a splicing block toy installs a take-up and pull line device suitable for splicing blocks at one end of a bottom plate block; the bottom plate building block can be a building block vehicle bottom plate or a force arm bottom plate building block extending out of a chariot, one end of the bottom plate building block is provided with a connecting female head which is inclined upwards, a rotating connector 104 of a frame assembly 1 of a winding and drawing device suitable for splicing the building block is connected with the connecting female head of the bottom plate building block, and a rotating assembly 2 is arranged in the inner concave surface of a concave component of the frame assembly 1; the elastic arm component of the rotating assembly is in rotating fit with the rotating shaft salient point on the frame, and the elastic arm component deforms to generate elasticity and prevent falling. The elastic arm component is similar to a tongue shape, a gap is reserved between the elastic arm component and the periphery, and a concave platform is arranged on the elastic arm component and can prevent the salient point of the rotating shaft from being separated. The rotating shaft convex point groove is in rotating fit with the rotating shaft convex point, and the damping convex point is in damping fit with the rotating shaft convex point groove of the rotating part, so that a click-click damping rotating effect is achieved. The pulling wire is wound on the wire take-up groove 203 of the rotating assembly 2 and passes through the wire threading hole 204 of the rotating assembly 2. One end of the stay wire far away from the rotating component 2 is connected with the tail part of the bottom plate of another building block vehicle, so that the situation that one splicing building block vehicle drags and pulls another splicing building block vehicle is realized, and the playing method that the primary and secondary war vehicles are connected together through the stay wire collecting device suitable for splicing building blocks to fight in a collaborative mode can also be realized.

In another variation, the floor block may be an aircraft carrier floor block, the other end of the pull wire is connected to the fighter plane block, and the player pulls the pull wire to move the fighter plane block linearly at a constant speed or at a non-constant speed in a deck area of the aircraft carrier floor block.

The invention has reasonable structure and convenient use, and can be well suitable for splicing building blocks, in particular large-particle spliced building blocks; in the invention, the elastic arm structure of the rotating assembly is in rotating fit with the rotating shaft salient point on the frame assembly, and the elastic arm structure deforms to generate elasticity and prevent falling. The elastic arm structure is similar to a tongue shape, a gap is reserved between the elastic arm structure and the periphery of the elastic arm structure, and a concave platform is arranged on the elastic arm structure and can prevent the salient point of the rotating shaft from being separated; according to the invention, the rotating shaft salient point groove is in rotating fit with the rotating shaft salient point, and the damping salient point is in damping fit with the rotating shaft salient point groove of the rotating part, so that a clicking and clicking damping rotating effect is realized, and the pleasure of splicing the building blocks in use is better increased.

Those skilled in the art will appreciate that, in addition to implementing the system and its various devices, modules, units provided by the present invention as pure computer readable program code, the system and its various devices, modules, units provided by the present invention can be fully implemented by logically programming method steps in the form of logic gates, switches, application specific integrated circuits, programmable logic controllers, embedded microcontrollers and the like. Therefore, the system and various devices, modules and units thereof provided by the invention can be regarded as a hardware component, and the devices, modules and units included in the system for realizing various functions can also be regarded as structures in the hardware component; means, modules, units for performing the various functions may also be regarded as structures within both software modules and hardware components for performing the method.

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

The foregoing description of specific embodiments of the present invention has been presented. It is to be understood that the present invention is not limited to the specific embodiments described above, and that various changes or modifications may be made by one skilled in the art within the scope of the appended claims without departing from the spirit of the invention. The embodiments and features of the embodiments of the present application may be combined with each other arbitrarily without conflict.

Claims (10)

1. The utility model provides a receive traditional thread binding putting suitable for concatenation building blocks which characterized in that includes: building block components, stay wire components;

the building element comprises: a first building element, a second building element, a bottom plate building element;

the first building element comprises: a rotating assembly (2);

the wire drawing member includes: a pull wire;

the pull wire is wound on the rotating assembly (2);

the second building element comprises: rotating the limiting assembly;

the rotating assembly (2) is connected with the rotating limiting assembly;

the rotating assembly (2) can rotate circumferentially around a central line formed by the rotating limiting assembly;

the second building element comprises: a frame assembly (1);

the frame assembly (1) comprises: a female member, a male member, a rotary connector (104) and a female connector (103);

the rotation limiting assembly is arranged on the inner concave surface of the concave component;

the rotary connector (104) is arranged on the male component;

the female connection end is disposed on an outer side of the female member.

2. A take-up and pull line device for splicing together construction blocks according to claim 1, wherein said first construction element comprises: a thumb wheel assembly (3);

the thumb wheel assembly (3) is arranged at one end of the rotating assembly (2);

the thumb wheel assembly (3)) can rotate circularly around a central line formed by the rotation limiting assembly.

3. A take-up and pull-off device for splicing building blocks according to claim 1, wherein the rotating assembly (2) comprises: a wire take-up groove (203);

the wire collecting groove is arranged in the middle of the rotating assembly (2);

the pull wire is wound on the wire collecting groove (203).

4. A take-up and pull-off device for splicing building blocks according to claim 1, wherein the rotating assembly (2) comprises: a threading hole (204);

the threading hole (204) is arranged in the middle of the rotating assembly (2);

the pull wire passes through the threading hole (204).

5. A take-up and pull-off device for splicing building blocks according to claim 1, wherein the rotating assembly (2) comprises: a click slot (202);

the bayonet groove (202) is arranged on the end face of one end of the rotating assembly (2).

6. A take-up and pull line device for splicing together construction blocks according to claim 1, wherein said second construction element comprises: a frame rear rotating member (4);

the frame rear rotating member (4) is disposed in the middle of the male member.

7. A take-up and pull-off device for splicing building blocks according to claim 5, wherein the frame assembly (1) comprises: a rotation shaft bump (102);

the rotating assembly (2) comprises: a rotating shaft cam groove (205);

the rotating shaft salient point groove (205) is matched with the rotating shaft salient point (102);

the rotating shaft salient point (102) is arranged on the inner concave surface of the concave component;

the rotating shaft convex point groove (205) is arranged on the end face of the other end of the rotating assembly (2).

8. A take-up and pull-off device for splicing building blocks according to claim 7, wherein the rotating assembly (2) comprises: an elastic arm member (201);

the elastic arm member (201) is arranged on one end face of the rotating assembly (2);

the elastic arm member (201) is arranged at the position adjacent to the click slot (202);

the elastic arm member (201) includes: spring arm concave platform structure.

9. The take-up and pull-out device suitable for splicing building blocks as claimed in claim 5, wherein the number of the click grooves (202) is multiple;

the plurality of clamping point grooves (202) are circumferentially arranged on the end face of one end of the rotating assembly (2);

the frame assembly (1) further comprises: a damping bump (101);

the damping salient point (101) is matched with the clamping point groove (202).

10. Splicing block, characterized in that the set assembly configuration is spliced by using the take-up and pull-off device suitable for splicing blocks as claimed in any one of claims 1-9.

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