CN216014598U - Novel plan sand table geometry building blocks mosaic structure - Google Patents

Abstract

The utility model discloses a novel plan sand table geometry building blocks mosaic structure, include: splice and splice seat. The splice comprises an outer joint and an inner joint, wherein the inner joint is arranged at the bottom of the outer joint. The splicing seat is provided with at least one slot, a clamping and connecting rod is arranged in the slot, and the clamping and connecting rod is used for clamping and connecting the inner clamping connector. The utility model provides an outer joint can set up outer draw-in groove or outer kelly on the joint, and outer draw-in groove and outer kelly match each other to link together a plurality of splices and the combination of concatenation seat. The splicing joints on the splicing seats can be changed in quantity, position and even type at will, and the splicing seats without splicing any splicing joints are regular in shape, so that the splicing of building blocks cannot be influenced. The planner can splice more shapes of building blocks according to different planning targets, and the visual effects of planning such as novel urbanization and village joy are greatly improved.

Description

Novel plan sand table geometry building blocks mosaic structure

Technical Field

The utility model relates to a building blocks technical field, in particular to novel plan sand table geometry building blocks mosaic structure.

Background

Compared with the traditional urban planning, the novel urbanization planning focuses on economic development and focuses on ecology and habitability, so that new requirements are provided for the novel urbanization planning. The model building block planning method has the advantages of being more visual and more changeable, can stimulate the inspiration of planners, and meets the requirements of people on good life.

Typically, the bricks have a protruding formation and a recessed formation, and the protruding formation and the recessed formation are generally matched to enable a plurality of bricks to be spliced together. In the existing building block product, the number and the positions of the protruding structures and the recessed structures on each building block are fixed, and a planner can only use the existing building block structure and cannot exert imagination to the maximum extent.

SUMMERY OF THE UTILITY MODEL

The embodiment of the utility model provides a novel plan sand table geometry building blocks mosaic structure for protruding structure and sunk structure quantity and position are all fixed on solving building blocks among the prior art, have the unsatisfactory problem of result of use.

On the one hand, the embodiment of the utility model provides a novel plan sand table geometry building blocks mosaic structure, include: a splicing head and a splicing seat;

the splicing joint comprises an outer clamping joint and an inner clamping joint, and the inner clamping joint is arranged at the bottom of the outer clamping joint;

the splicing seat is provided with at least one slot, a clamping and connecting rod is arranged in the slot, and the clamping and connecting rod is used for clamping and connecting the inner clamping connector.

In one possible implementation, an outer clamping rod is arranged on the outer clamping connector.

In a possible implementation manner, the outer clamping joint is provided with an outer clamping groove.

In one possible implementation, the opening width of the external clamping groove is smaller than the maximum width of the external clamping groove, and the external clamping connector is made of elastic materials.

In a possible implementation mode, the inner clamping joint is provided with an inner clamping groove, and the inner clamping groove is matched with the clamping rod.

In one possible implementation, the opening width of the inner clamping groove is smaller than the maximum width of the inner clamping groove, and the inner clamping connector is made of elastic materials.

In one possible implementation, the inner snap groove is a cylindrical groove.

In one possible implementation, the inner clamping groove is a spherical groove.

In a possible implementation manner, at least one elastic seam is formed on the inner clamping connector.

In a possible implementation manner, a clamping ball is arranged on the clamping rod and matched with the inner clamping groove.

The utility model provides a novel plan sand table geometry building blocks mosaic structure has following advantage:

the outer clamping joint can be provided with an outer clamping groove or an outer clamping rod, and the outer clamping groove and the outer clamping rod are matched with each other so as to connect the combination of the splicing joints and the splicing seats together. The splicing joints on the splicing seats can be changed in quantity, position and even type at will, and the splicing seats without splicing any splicing joints are regular in shape, so that the splicing of building blocks cannot be influenced. The planner can splice more shapes of building blocks as required, and the visual effect of planning such as novel urbanization, country happy and the like is greatly improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic diagram of an un-spliced state of a novel splicing structure for planning geometric building blocks of a sand table according to a first embodiment of the present invention;

fig. 2 is a schematic diagram of a splicing state of a novel splicing structure of geometric building blocks for planning a sand table according to a first embodiment of the present invention;

fig. 3 is an internal schematic view of a splicing state of a novel splicing structure for planning geometric building blocks of a sand table according to a first embodiment of the present invention;

fig. 4 is a schematic view of a partial structure of a splice in a novel splicing structure of geometric building blocks for a sand table according to a second embodiment of the present invention;

fig. 5 is an internal schematic diagram of a non-spliced state of the novel geometric building block splicing structure for planning sand tables provided by the second embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Fig. 1, fig. 2 and fig. 3 are schematic diagrams illustrating a splicing structure of novel geometric building blocks for planning sand tables according to a first embodiment of the present invention. The embodiment of the utility model provides a novel plan sand table geometric building blocks mosaic structure, include: a splice 100 and a splice holder 200;

the splice 100 includes an outer bayonet joint 110 and an inner bayonet joint 130, the inner bayonet joint 130 being disposed at the bottom of the outer bayonet joint 110;

the splicing seat 200 is provided with at least one slot 210, a clamping rod 220 is arranged inside the slot 210, and the clamping rod 220 is used for clamping the inner clamping connector 130.

Illustratively, the socket 200 may be a cylindrical or prismatic rod, and the number of the slots 210 provided thereon may be plural, for example, when the socket 200 has a quadrangular prism structure, the slots 210 may be opened on each side thereof, that is, the number of the slots 210 is four. When the number of the slots 210 on the splicing seat 200 is multiple, the slots 210 should be communicated with each other, and the position where the slots 210 are communicated should be at the central position inside the splicing seat 200, and the clamping rod 220 is located at the central position, so that the splicing head 100 inserted into any slot 210 can be plugged onto the clamping rod 220.

In one possible embodiment, an outer bayonet lever is provided on the outer bayonet joint 110.

Illustratively, an external card slot 111 may be further disposed on the external card connector 110 corresponding to the external card rod, and the external card slot 111 is matched with the external card rod. It is to be understood that one of the outer bayonet bar and the outer bayonet groove 111 may be provided on the outer bayonet joint 110, or the outer bayonet bar and the outer bayonet groove 111 may be provided on the outer bayonet joint 110 at the same time.

In the embodiment of the present invention, the outer clip rod may have a cylindrical, elliptic cylindrical, or prismatic structure, and the outer clip groove 111 has a shape matching with the outer clip rod. After the splice 100 is inserted into the slots 210 of the splice holder 200, the combination of the splice holder 200 and the splice 100 can be spliced together by the cooperation of the outer clamping bar and the outer clamping groove 111 of the splice 100.

In one possible embodiment, the opening width of the external card slot 111 is smaller than the maximum width of the external card slot 111, and the external card connector 110 is made of an elastic material.

Illustratively, since the outer bayonet groove 111 is matched with the outer bayonet rod, the opening width of the outer bayonet groove 111 is also smaller than the width of the outer bayonet rod. When needs splice, can insert outer draw-in groove 111 from the opening part of outer draw-in groove 111 with outer kelly, can take place elastic deformation at outer joint head 110 of male in-process, after outer draw-in groove 111 is inserted completely to outer draw-in rod, outer joint head 110 resumes and with the stable joint of outer draw-in rod in outer draw-in groove 111.

The utility model discloses an in the embodiment, for further increase the frictional force between outer kelly and the outer draw-in groove 111, prevent that outer kelly from rotating at will in outer draw-in groove 111, lead to building blocks to take place to warp, can be at the inside one deck skid resistant course that sets up of outer draw-in groove 111, perhaps set up graininess arch on the lateral surface of outer kelly and/or the medial surface of outer draw-in groove 111.

In one possible embodiment, the inner bayonet joint 130 has an inner bayonet 131 formed thereon, and the inner bayonet 131 is matched with the bayonet rod 220.

Illustratively, the outer bayonet joint 110 is provided with a connecting rod 120 on a bottom surface thereof, and the inner bayonet joint 120 is provided on a bottom surface of the connecting rod 120. The external card connector 110 may be detachably connected with the connection rod 120 to replace a different type of external card connector 110, i.e., to replace the external card connector 110 having the external card slot 111 or having the external card rod.

In one possible embodiment, the opening width of inner card slot 131 is less than the maximum width of inner card slot 131, and inner card connector 130 is made of an elastic material.

Illustratively, since inner bayonet slot 131 mates with bayonet rod 220, the width of the opening of inner bayonet slot 131 is also less than the width of bayonet rod 220. When splicing is needed, the opening of the inner clamping groove 131 can be aligned with the clamping rod 220, the clamping rod 220 is inserted into the inner clamping groove 131 through the opening, the inner clamping connector 130 can be elastically deformed in the inserting process, and after the clamping rod 220 is completely inserted into the inner clamping groove 131, the inner clamping connector 130 recovers and stably clamps the clamping rod 220 in the inner clamping groove 131.

The utility model discloses an in the embodiment, for further increase the frictional force between joint pole 220 and interior draw-in groove 131, prevent that joint pole 220 from rotating at will or sliding in draw-in groove 131 including, lead to building blocks to take place to warp, draw-in groove 131 is inside to set up one deck skid resistant course including, perhaps sets up graininess arch on the lateral surface of joint pole 220 and/or the medial surface of interior draw-in groove 131.

In one possible embodiment, internal card slot 131 is a cylindrical slot.

Illustratively, snap rod 220 is also a cylindrical rod, corresponding to inner snap 131, having a diameter comparable to the maximum width of inner snap 131.

Fig. 4 and fig. 5 are schematic diagrams of a splicing structure of a novel geometric building block for planning sand tables according to a second embodiment of the present invention. In one possible embodiment, inner card slot 131 is a spherical slot.

Illustratively, clamping rod 220 is provided with a clamping ball 221 corresponding to inner clamping groove 131, and clamping ball 221 is matched with inner clamping groove 131, i.e. the diameter of clamping ball 221 is matched with the inner diameter of inner clamping groove 131.

For making joint ball 221 can normally insert interior draw-in groove 131, at least one elasticity seam 132 that need have also been seted up on interior joint 130, and elasticity seam 132 and interior draw-in groove 131 intercommunication, when making interior joint 130 receive the extrusion of joint ball 221, interior joint 130 can take place elastic deformation, the width of elastic seam 132 can grow when taking place elastic deformation, after interior draw-in groove 131 is inserted completely to joint ball 221, interior joint 130 resumes and with the stable joint of joint ball 221 in interior draw-in groove 131.

In the embodiment of the present invention, the center of the clamping ball 221 is located on the axis of the clamping rod 220, so that the inner clamping head 130 can be spliced with the clamping ball 221 in the same state from any angle. Since the catching ball 221 is disposed inside the splicing seat 200 by the catching bar 220, when the catching ball 221 is inserted into the inner catching groove 131, the inner catching head 130 also contacts the catching bar 220. The width of the elastic slit 132 may be the same as that of the catching bar 220, so that the catching bar 220 can be inserted into the elastic slit 132 to prevent interference with the catching ball 221 and the inner catching groove 131.

While the preferred embodiments of the present invention have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. It is therefore intended that the appended claims be interpreted as including the preferred embodiment and all such alterations and modifications as fall within the scope of the invention.

It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (10)

1. The utility model provides a novel plan sand table geometry building blocks mosaic structure which characterized in that includes: a splice (100) and a splice holder (200);

the splice (100) comprises an outer bayonet joint (110) and an inner bayonet joint (130), wherein the inner bayonet joint (130) is arranged at the bottom of the outer bayonet joint (110);

be provided with at least one slot (210) on concatenation seat (200), slot (210) inside is provided with joint pole (220), joint pole (220) are used for the joint interior joint head (130).

2. The novel splicing structure for planning geometric building blocks of sand tables as claimed in claim 1, wherein said outer bayonet joint (110) is provided with an outer bayonet rod.

3. The novel splicing structure for planning geometric building blocks of a sand table as claimed in claim 1, wherein the outer bayonet joint (110) is provided with an outer bayonet groove (111).

4. A novel splicing structure for planning geometric building blocks of sand table according to claim 3, wherein the opening width of said external clamping groove (111) is smaller than the maximum width of said external clamping groove (111), and said external clamping head (110) is made of elastic material.

5. The novel splicing structure for planning geometric building blocks of a sand table as claimed in claim 1, wherein the inner bayonet joint (130) is provided with an inner bayonet slot (131), and the inner bayonet slot (131) is matched with the clamping rod (220).

6. A novel splicing structure for planning geometric building blocks of sand tables as claimed in claim 5, wherein the opening width of said inner snap groove (131) is smaller than the maximum width of said inner snap groove (131), and said inner snap joint (130) is made of elastic material.

7. The novel splicing structure of planning sand table geometric building blocks as claimed in claim 6, wherein said inner slot (131) is a cylindrical slot.

8. A novel splicing structure for planning geometric building blocks of a sand table as claimed in claim 6, wherein said inner slots (131) are spherical slots.

9. The novel splicing structure of planning sand table geometric building blocks as claimed in claim 8, wherein said inner snap joint (130) is provided with at least one elastic seam (132).

10. A novel splicing structure for planning geometric building blocks of sand tables as claimed in claim 8, wherein said snap rod (220) is provided with a snap ball (221), and said snap ball (221) is matched with said inner snap groove (131).

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