CN218942580U - Spliced magic square plate - Google Patents

Abstract

The application belongs to the technical field of furniture accessories, and particularly relates to a spliced magic cube board, which comprises a base plate and a plurality of frame components; each frame component comprises a main frame body, a cover body, at least one plug hook structure and at least one unlocking structure, wherein the plug hook structure comprises a hook body piece, an auxiliary unlocking piece and a first elastic piece, and the unlocking structure comprises a button, an auxiliary resetting piece, a second elastic piece and a third elastic piece; the hook body part is provided with a barb end, the hook body part is rotatably arranged on the main frame body, and the barb end can be rotated out of the assembly space of the main frame body so as to be directly inserted and buckled on the frame component of the other spliced magic square plate; the unlocking structure is used for rapidly unlocking the inserting hook structure so as to separate from the frame component of the other spliced magic cube plate. The application of the grid cabinet aims at solving the problems that the disassembly and assembly process of the grid cabinet with the existing combined structure is very complicated, time-consuming and labor-consuming.

Description

Spliced magic square plate

Technical Field

The application belongs to furniture accessory technical field, especially relates to a concatenation magic cube board.

Background

The user needs to use the cabinet to put some articles, so that the articles are orderly put, the articles can be conveniently and rapidly found when the user needs to use the cabinet, and the household space can be tidy and attractive. However, most of the existing lattice cabinets adopt a combined structure, but the area and the volume of each plate are relatively large, so that the assembling process of users is time-consuming and labor-consuming. Moreover, the check cabinet is difficult to disassemble after the assembly is completed, when a user needs to move the check cabinet to a replacement position, the user either moves the whole check cabinet to a new position or reassembles the check cabinet at the new position after the tedious disassembly is carried out, which is time-consuming and labor-consuming and complex in process.

Therefore, the disassembly and assembly process of the grid cabinet with the existing combined structure is very tedious, time-consuming and labor-consuming.

Disclosure of Invention

The utility model aims at providing a concatenation magic cube board aims at solving the very loaded down with trivial details, the problem that wastes time and energy of dismouting process of the check cabinet of current combined structure.

In order to achieve the above purpose, the technical scheme adopted in the application is as follows: a spliced cube panel comprising:

a substrate;

the frame components are arranged around and fixed on the periphery of the substrate; wherein,,

each frame component comprises a main frame body, a cover body, at least one inserting hook structure and at least one unlocking structure, wherein the cover body covers the main frame body to form an assembling space, the inserting hook structure and the unlocking structure are both arranged in the assembling space, the main frame body is provided with a third penetrating outlet and a fourth penetrating outlet which are communicated with the assembling space, the inserting hook structure comprises a hook body piece, an auxiliary unlocking piece and a first elastic piece, the hook body piece is provided with a barb end, the hook body piece is rotatably arranged on the main frame body, the barb end can rotate out of or rotate into the assembling space from the third penetrating outlet, the hook body piece is provided with a matching groove, the position of the groove bottom of the matching groove close to the barb end is provided with a first inclined plane, one side groove wall of the matching groove is provided with a second avoiding opening, two ends of the auxiliary unlocking piece are respectively provided with a second inclined plane and a third inclined plane, and the side wall of the auxiliary unlocking piece is provided with a reset protrusion, the auxiliary unlocking piece is arranged in the matching groove, the resetting bulge is arranged in the second avoidance opening, the first elastic piece is arranged between the side wall of the resetting bulge facing the barb end and the side wall of the avoidance opening, the first inclined surface and the second inclined surface can slide relatively, the unlocking structure comprises a button, an auxiliary resetting piece, a second elastic piece and a third elastic piece, the button can slide and is arranged in the main frame body, the second elastic piece is used for providing the button with elastic force for enabling the button to move towards the fourth through opening, the side edge of the button, deviating from the fourth through opening, abuts against the third inclined surface when the barb end rotates out of the third through opening, the auxiliary resetting piece slides and is arranged in the main frame body, and the third elastic piece is arranged between the auxiliary resetting piece and the main frame body so as to apply elastic force for enabling the auxiliary resetting piece to move towards the plug hook structure.

The application has at least the following beneficial effects:

the utility model provides a concatenation magic cube board is mutually supported through the hook structure and the unblock structure and is spliced perpendicularly to the magic cube board for integrated into one piece is the check cabinet between the many magic cube boards, and can conveniently, swiftly carry out mutual dismouting between hook structure and the unblock structure, realized convenient, swift dismouting's purpose, the user can recycle this concatenation magic cube board moreover, convenient and practical.

In one embodiment, the unlocking structure further comprises a fifth pin shaft, the button is installed in the assembly space through the fifth pin shaft, the button can slide back and forth along the central axis direction of the fifth pin shaft, and the second elastic piece is sleeved on the fifth pin shaft and provides elastic force for enabling the button to move towards the fourth penetrating opening.

In one embodiment, a fourth inclined plane is arranged on one side of the button, which is away from the inserting hook structure, and the side edge of the auxiliary resetting piece, which exceeds the inserting hook structure, can be abutted with the fourth inclined plane and slide relatively.

In one embodiment, each frame component further comprises at least one buckling structure, the buckling structure is mounted in the assembly space, the main frame body is further provided with a first penetrating opening and a second penetrating opening which are communicated with the assembly space, the buckling structure comprises a sliding part and a clasp part, the sliding operation end of the sliding part penetrates out of the first penetrating opening and can slide along the extending direction of the first penetrating opening, the clasp part is provided with an arc sliding hole and a clasp part, the sliding part is connected with the arc sliding hole through a first pin shaft, the first pin shaft can move along the arc sliding hole, the clasp part is rotatably mounted in the main frame body, and the clasp part extends to the second penetrating opening.

In one embodiment, the buckling structure further comprises a connecting rod and a pushing piece, two ends of the connecting rod are respectively connected with the clasp piece and the pushing piece in a rotating mode, the connecting rod is installed in the main frame in a rotating mode, the pushing piece can be installed in the main frame in a sliding mode, the clasp piece drives the pushing piece to reciprocate along the connecting line direction between the pushing piece and the second penetrating opening through the connecting rod, and the pushing piece faces to the end face of the second penetrating opening and is arranged at intervals with the clasp portion.

In one embodiment, the buckling structure further comprises a limiting piece, the limiting piece forms a C-shaped space, the limiting piece is provided with a first avoidance opening, the connecting rod is provided with a limiting protrusion, the limiting protrusion is arranged in the C-shaped space and is correspondingly located in the first avoidance opening, the limiting piece is fixedly mounted to the main frame body, the limiting piece is provided with a propping end face, the propping end face faces the clasp part and the pushing piece, and the propping end face is used for propping against the limiting clasp part and the pushing piece when the clasp part is in a buckling state.

In one embodiment, the clasp member is further provided with a first rotation hole, the clasp member is rotatably mounted on the main frame body through the first rotation hole and the second pin shaft, the first rotation hole is a long-strip-shaped through hole, and the extending direction of the first rotation hole is consistent with the extending direction of the first penetrating hole.

In one embodiment, the pushing piece is provided with a pushing connecting hole, the pushing piece is connected to one end of the connecting rod through the pushing connecting hole matched with the third pin shaft, the pushing connecting hole is provided with a strip-shaped through hole, and the extending direction of the pushing connecting hole is consistent with the extending direction of the first penetrating opening.

In one embodiment, the pushing member is provided with a guide projection, a guide groove is provided on a cavity wall of the assembly space of the main frame body, the guide projection is inserted into the guide groove, and the guide projection can slide back and forth along the guide groove.

In one embodiment, the cover body is provided with a clamping protrusion, the main frame body is provided with a clamping groove, and the clamping protrusion is positioned and clamped in the clamping groove; and/or one side of the main frame body, which faces the substrate, is provided with a positioning protrusion and an inserting block, and the side of the substrate is provided with a positioning groove matched with the positioning protrusion and an inserting groove matched with the inserting block.

Through the polylith concatenation magic cube board that uses this application to provide, not only can carry out the flattening concatenation and form bigger surface to the adaptation tiling is on the desktop, or the adaptation is laid on the wall, but also can carry out the perpendicular concatenation, thereby the combination forms the check cabinet and supplies the user to put article. Because the concatenation magic cube board that this application provided carries out the flattening concatenation to two adjacent magic cube boards through the lock structure to carry out perpendicular concatenation through inserting hook structure and unblock structure to the magic cube board and form the check cabinet, realized convenient, swift dismouting's purpose, the user can recycle this concatenation magic cube board moreover, convenient and practical.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required for the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a spliced magic cube board according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of the two spliced magic cube boards according to the embodiment of the present application after being spliced;

fig. 3 is a schematic structural diagram of three spliced magic square plates according to an embodiment of the present application, where two of the three magic square plates are spliced in a flat manner, and the third magic square plate is spliced vertically with the first two magic square plates;

FIG. 4 is an exploded view of one of the edge frame assemblies in the spliced cube panel of the embodiments of the present application;

fig. 5 is a schematic structural diagram of a main frame of a spliced magic cube board according to an embodiment of the present application;

FIG. 6 is a schematic view of a clasp of a splice cube panel according to an embodiment of the disclosure;

fig. 7 is a schematic structural diagram of a connecting rod of a spliced magic cube board according to an embodiment of the present application;

fig. 8 is a schematic structural view of a pushing member of a spliced magic cube board according to an embodiment of the present application;

FIG. 9 is a schematic structural view of a limiter of a spliced magic cube panel according to an embodiment of the present application;

fig. 10 is a schematic structural diagram of a hook member of a spliced magic cube board according to an embodiment of the present application;

FIG. 11 is a second schematic structural view of hook members of a spliced magic cube board according to the embodiment of the present application;

fig. 12 is a schematic structural view of an auxiliary unlocking member and a first elastic member according to an embodiment of the present application;

FIG. 13 is a schematic view of the structure of a button according to an embodiment of the present application;

fig. 14 is a schematic structural view of an auxiliary restoring member according to an embodiment of the present application.

Wherein, each reference sign in the figure:

10. a substrate; 11. a positioning groove; 12. a plug-in groove;

20. a frame assembly; 21. a main frame; 211. a first through-outlet; 212. a second exit orifice; 213. a clamping groove; 214. positioning the bulge; 215. an insert block; 216. a third exit port; 217. a fourth through outlet; 22. a cover body; 221. a clamping protrusion; 23. a buckling structure; 231. a sliding pushing piece; 2311. the sliding operation end; 232. a clasp member; 2321. an arc slide hole; 2322. a first rotation hole; 2323. a clasp part; 233. a first pin; 234. a second pin; 235. a third pin; 236. a connecting rod; 2361. a first connection hole; 2362. a second connection hole; 2363. a second rotation hole; 2364. a limit protrusion; 237. a pushing member; 2371. pushing the connecting hole; 2372. a guide projection; 238. a restriction member; 2381. a first avoidance port; 2382. a top end surface; 2383. c-shaped space; 24. a hook inserting structure; 241. a hook member; 2411. a barb end; 2412. a mating groove; 2413. a second avoidance port; 2414. a first inclined surface; 242. an auxiliary unlocking piece; 2421. a second inclined surface; 2422. a third inclined surface; 2423. resetting the bulge; 243. a first elastic member; 25. an unlocking structure; 251. a button; 2511. a third connection hole; 2512. a fourth connection hole; 2513. a fourth inclined surface; 252. an auxiliary reset member; 2521. a sliding ear; 253. a second elastic member; 254. a fifth pin; 255. a third elastic member; 26. and a fourth pin shaft.

Detailed Description

Embodiments of the present application are described in detail below, examples of which are illustrated in the accompanying drawings, wherein the same or similar reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below by referring to the drawings are exemplary and intended for the purpose of explaining the present application and are not to be construed as limiting the present application.

In the description of the present application, it should be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate description of the present application and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present application.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second", etc. may explicitly or implicitly include one or more such feature. In the description of the present application, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In this application, unless specifically stated and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art as the case may be.

As shown in fig. 1, the spliced magic cube board comprises a base board 10 and four frame components 20, wherein the base board 10 is in a rectangular outline shape, and the four frame components 20 are fixedly arranged around the periphery of the base board 10 in an end-to-end mode, so that the magic cube board is integrally formed. Each of the frame assemblies 20 is secured to a corresponding side of the base plate 10 by a screw connection.

As shown in fig. 4 and 5, the frame assembly 20 includes a main frame 21 and a cover 22, the cover 22 is fastened to the side of the main frame 21 facing the substrate 10, and an assembly space is formed between the main frame 21 and the cover 22. As shown in fig. 4, the frame assembly 20 further includes at least one fastening structure 23, and the fastening structure 23 is installed in the assembly space.

As shown in fig. 4 and 6, the fastening structure 23 includes a sliding member 231, a clasp member 232, a first pin 233, and a second pin 234. Correspondingly, the main frame 21 is provided with a first strip-shaped penetrating outlet 211 communicated with the assembly space, and the side wall of the main frame 21, which is away from the substrate 10, is provided with a second penetrating outlet 212 communicated with the assembly space. The sliding member 231 is assembled in the assembling space, and the sliding operation end 2311 of the sliding member 231 is penetrated out from the first penetrating hole 211 for a user to perform a sliding operation on the sliding member 231, so that the sliding member 231 can reciprocally slide along the first penetrating hole 211. As shown in fig. 6, the clasp 232 is provided with an arcuate slide hole 2321, a first rotation hole 2322, and a clasp portion 2323. The clasp 232 is assembled in the assembly space, and the clasp 2323 extends toward the second outlet 212, but the clasp 2323 does not pass out of the second outlet 212, as shown in fig. 1. The first pin 233 passes through the arc-shaped sliding hole 2321, and both ends of the first pin 233 are fixedly installed on the sliding member 231. The second pin shaft 234 passes through the first rotating hole 2322, and the first rotating hole 2322 is set to be a long-strip-shaped through hole, the extending direction of the first rotating hole 2322 is consistent with the extending direction of the first penetrating hole 211, two ends of the second pin shaft 234 are fixedly arranged on two opposite side cavity walls of the assembly space, so that the clasp piece 232 can rotate around the central axis of the second pin shaft 234, and the second pin shaft 234 can move along the long-strip-shaped first rotating hole 2322 relative to the clasp piece 232 in the process that the clasp piece 232 rotates around the central axis of the second pin shaft 234.

As such, when the user pushes the sliding member 231 to slide along the first penetrating hole 211, the first pin 233 will slide along the arc track of the arc sliding hole 2321, thereby rotating the clasp 232 around the central axis of the second pin 234. At this time, the clasp 2323 performs an opening action or a closing action accordingly.

Referring to fig. 2 in combination, when a user splices two spliced cube panels to extend an area, one frame assembly 20 of a first spliced cube panel is opposed to one frame assembly 20 of a second spliced cube panel. Then, the user pushes the sliding members 231 of the two frame assemblies 20 of the two spliced magic cube panels horizontally, so that the respective clasp portions 2323 perform the opening action. Next, the user inserts two clasp portions 2323 of two splice cube plates into respective second pass-through openings 212. Then, the user pushes the two slide pushers 231 in opposite directions so that the two clasp portions 2323 hang each other. Thus, the clasp 2323 and the second through-hole 212 of the first splicing cube board firmly limit the clasp 2323 of the second splicing cube board, and correspondingly, the clasp 2323 and the second through-hole 212 of the second splicing cube board firmly limit the clasp 2323 of the first splicing cube board, so that the two splicing cube boards are firmly spliced together, and the purpose of extending the area is achieved.

By using the spliced magic cube board provided by the application, the frame assembly 20 which is connected end to end and fixed on the periphery of the substrate 10 is arranged around the periphery of the substrate 10, the buckling structure 23 is ingeniously designed in the frame assembly 20, and the two spliced magic cube boards can be mutually hung and buckled through the buckling parts 2323 of the buckling pieces 232 of the buckling structures 23, so that the two spliced magic cube boards are conveniently, quickly and firmly spliced together in a flat manner, and the purpose of expanding the surface area is realized. Like this, through utilizing the polylith concatenation magic cube board to carry out the flattening concatenation and form bigger surface to can adapt to tiling on the desktop, perhaps can adapt to be spread on the wall. Moreover, the splicing magic cube plates are used for flattening and splicing to form a larger surface, two adjacent splicing magic cube plates can be conveniently and rapidly disassembled through the buckling structure 23, then a new splicing magic cube plate is replaced, and a user can recycle the splicing magic cube plates, so that the novel splicing magic cube is convenient and practical.

Further, as shown in fig. 4, 7 and 8, the fastening structure 23 further includes a third pin 235, a connecting rod 236 and a pushing member 237. As shown in fig. 7, the two ends of the link 236 are respectively provided with a first connection hole 2361 and a second connection hole 2362, and the middle position of the link 236 is provided with a second rotation hole 2363, and as shown in fig. 8, the pushing member 237 is provided with a pushing connection hole 2371. The second pin 234 passes through the second rotation hole 2363 such that the link 236 can rotate about the central axis of the second pin 234. The first pin 233 passes through the first connection hole 2361, and when the sliding member 231 slides, the sliding member 231 drives the link 236 to rotate around the central axis of the second pin 234 through the first pin 233. The third pin shaft 235 sequentially passes through the second connecting hole 2362 and the pushing connecting hole 2371, and two ends of the third pin shaft 235 are fixedly mounted on the cavity walls on two opposite sides of the assembly space, so that when the sliding member 231 slides to enable the clasp 2323 to perform opening movement, the sliding member 231 drives the connecting rod 236 to rotate around the central axis of the second pin shaft 234 through the first pin shaft 233, and the connecting rod 236 drives the pushing member 237 to move towards the direction close to the second through hole 212 through the third pin shaft 235. The pushing connection hole 2371 is configured as a long-strip-shaped through hole, and the extending direction of the pushing connection hole 2371 is consistent with the extending direction of the first through hole 211, so that in the process that the third pin 235 applies a pushing force to the pushing member 237 to enable the pushing member 237 to move towards the direction close to the second through hole 212, the third pin 235 can move along the long-strip-shaped pushing connection hole 2371 relative to the pushing member 237. Moreover, the pushing piece 237 is arranged towards the end face of the second through hole 212 and the hook portions 2323 at intervals, when the hook portions 2323 of the second splicing cube board are inserted into the second through hole 212 of the first splicing cube board, and the two hook portions 2323 are mutually hung and buckled to be limited, the hook portions 2323 of the second splicing cube board are limited in the interval between the pushing piece 237 and the hook portions 2323 of the first splicing cube board, and correspondingly, the hook portions 2323 of the first splicing cube board are limited in the interval between the pushing piece 237 and the hook portions 2323 of the second splicing cube board.

Thus, when the user splices the two spliced magic cube plates to extend the area, referring to fig. 2, the user pushes the sliding members 231 of the two frame assemblies 20 of the two spliced magic cube plates to each other, so that the respective clasp portions 2323 perform the opening action, at this time, the sliding members 231 drive the connecting rod 236 to rotate around the central axis of the second pin 234 through the first pin 233, and the connecting rod 236 drives the pushing member 237 to move towards the direction close to the second through hole 212 through the third pin 235. Then, the user inserts the two clasp portions 2323 of the two splicing cube plates into the corresponding second through-holes 212, so that the clasp portion 2323 of the first splicing cube plate abuts against the pushing member 237 of the second splicing cube plate, and the clasp portion 2323 of the corresponding second splicing cube plate abuts against the pushing member 237 of the first splicing cube plate. Then, the user forcefully inserts the two clasp portions 2323 into the corresponding second through holes 212, so that the clasp portions 2323 of the first splicing cube board push the pushing piece 237 of the second splicing cube board to move in a direction away from the second through holes 212, the pushing piece 237 of the second splicing cube board drives the connecting rod 236 to rotate and drives the sliding piece 231 to slide reversely, the clasp portions 2323 of the second splicing cube board and the second through holes 212 firmly limit the clasp portions 2323 of the first splicing cube board, and correspondingly, the clasp portions 2323 of the first splicing cube board and the second through holes 212 simultaneously firmly limit the clasp portions 2323 of the second splicing cube board, so that the two splicing cube boards are firmly spliced together, and the purpose of expanding an area is achieved.

As shown in fig. 4 and 9, in order to provide a more accurate movement position of the clasp 232 and pusher 237, the snap structure 23 further includes a limiter 238. The restriction 238 forms a C-shaped space 2383, and the restriction 238 is provided with a first escape opening 2381. A limiting protrusion 2364 is provided at a middle position of the connecting rod 236. In the specific assembly, the limiting protrusion 2364 is disposed in the C-shaped space 2383, and the limiting protrusion 2364 is correspondingly disposed in the first avoiding opening 2381, so that the mounting position of the connecting rod 236 is defined by the C-shaped space 2383 and the first avoiding opening 2381. Both ends of the restriction member 238 are then coupled to the main frame 21 (or both ends of the restriction member 238 and the second rotation hole 2363 are passed through by the second pin shaft 234, and then both ends of the second pin shaft 234 are fixedly mounted to the main frame 21). After the clasp 232 and the pusher 237 are respectively connected to the two ends of the connecting rod 236, the top end surface 2382 of the limiting member 238 abuts against and limits the clasp 232 and the pusher 237 when the clasp 2323 is in the locked state, so that the clasp 232 and the pusher 237 stop moving, that is, the clasp 2323 is locked in place.

As shown in fig. 8, the pushing member 237 is provided with a guide projection 2372, and correspondingly, a guide groove (not shown) is provided in a wall of the fitting space of the main frame 21. The guide projection 2372 is inserted into the guide groove, and the guide projection 2372 slides reciprocally along the guide groove (i.e., the pusher 237 moves in a direction approaching the second penetrating port 212 or moves in a direction separating from the second penetrating port 212), so that the sliding track of the pusher 237 is more stable.

In order to enable the cover 22 to be more quickly and stably covered on the main frame 21, as shown in fig. 4, the two ends of the cover 22 are provided with the locking protrusions 221, and correspondingly, as shown in fig. 5, the main frame 21 is provided with the locking grooves 213. The locking protrusion 221 is locked in the locking groove 213, so that the cover 22 can be covered on the main frame 21 more quickly and more stably.

Further, as shown in fig. 5, a positioning protrusion 214 is disposed on a side of the main frame 21 facing the substrate 10, and correspondingly, as shown in fig. 4, a positioning groove 11 is disposed on a side of the substrate 10. In fixedly mounting frame assembly 20 to the corresponding side of substrate 10, alignment tabs 214 are first aligned with alignment slots 11 and inserted into alignment slots 11 so that frame assembly 20 is quickly positioned between substrate 10 and the corresponding side of substrate 10. Then, the main frame 21 is locked to the substrate 10 by screws.

In order to stabilize the relative position between the frame assembly 20 and the base plate 10, therefore, as shown in fig. 5, the side of the main frame 21 facing the base plate 10 is provided with an insert block 215, and correspondingly, as shown in fig. 4, the side of the base plate 10 is provided with an insert groove 12. When the bezel assembly 20 is fixedly mounted to the corresponding side of the base plate 10, the positioning projections 214 are aligned with the positioning grooves 11 and the insert pieces 215 are simultaneously aligned with the insert grooves 12, and the positioning projections 214 are inserted into the positioning grooves 11 and the insert pieces 215 are inserted into the insert grooves 12. Then, the main frame 21 is locked to the substrate 10 by screws.

In the present embodiment, each frame assembly 20 is preferably provided with two snap features 23, with the two snap features 23 being spaced apart. Also, in the two fastening structures 23 of each frame component 20, the fastening portions 2323 of the two fastening members 232 respectively extend in opposite directions.

On the other hand, the user can also use the concatenation magic cube board that this application provided to make up and form the check cabinet (see the fig. 3 and show) to be used for putting article, thereby can find fast when conveniently needing to use article, also can make the house space appear clean and tidy, pleasing to the eye.

In the spliced magic cube, as shown in fig. 4, each frame assembly 20 further includes at least one inserting hook structure 24 and at least one unlocking structure 25, where the inserting hook structure 24 and the unlocking structure 25 are both installed in the assembly space, and correspondingly, the main frame body 21 is provided with at least one third penetrating opening 216 corresponding to the inserting hook structure 24 and at least one fourth penetrating opening 217 corresponding to the unlocking structure 25.

As shown in fig. 4 and fig. 10 to fig. 12, the hook structure 24 includes a hook body 241, an auxiliary unlocking member 242 and a first elastic member 243. The hook member 241 is rotatably mounted to the main frame 21 via the fourth pin 26. As shown in fig. 10 and 11, the hook 241 is provided with a barb end 2411, and the hook 241 can be rotated about the central axis of the fourth pin 26 so that the barb end 2411 is rotated out of the fitting space from the third penetrating outlet 216 or is rotated into the fitting space from the outside from the third penetrating outlet 216. As shown in fig. 10 and 11, the hook 241 is further provided with a fitting groove 2412 extending along a length direction thereof, a second escape opening 2413 is provided in a groove wall on one side of the fitting groove 2412, and a position of a groove bottom of the fitting groove 2412 near the barb end 2411 is set as a first inclined surface 2414. Accordingly, as shown in fig. 12, the auxiliary unlocking piece 242 is provided with a second slope 2421 and a third slope 2422 at both ends thereof, and the side wall of the auxiliary unlocking piece 242 is provided with a reset protrusion 2423, the auxiliary unlocking piece 242 is placed in the fitting groove 2412, and the reset protrusion 2423 is located in the second escape opening 2413. The first inclined surface 2414 can be matched with the second inclined surface 2421, and when the first inclined surface 2414 and the second inclined surface 2421 slide close to each other, the first inclined surface 2414 pushes the second inclined surface 2421 to gradually disengage the auxiliary unlocking piece 242 from the matching groove 2412. Further, a first elastic member 243, preferably a coil spring, is mounted between the sidewall of the return protrusion 2423 facing the barbed end 2411 and the sidewall of the opposite second escape opening 2413, and when the first inclined surface 2414 and the second inclined surface 2421 slide close to each other, the first elastic member 243 is further compressed, so that the first elastic member 243 applies an elastic force to the auxiliary unlocking member 242 to move the second inclined surface 2421 of the auxiliary unlocking member 242 away from the first inclined surface 2414.

As shown in fig. 4, 13 and 14, the unlocking structure 25 includes a button 251, an auxiliary restoring member 252, a second elastic member 253, a fifth pin 254, and a third elastic member 255. Among them, the second elastic member 253 and the third elastic member 255 are preferably coil springs.

As shown in fig. 13, the button 251 is provided with a third connection hole 2511 and a fourth connection hole 2512 at opposite sides thereof, two fifth pins 254 pass through the third connection hole 2511 and the fourth connection hole 2512, respectively, both ends of the two fifth pins 254 are mounted on the main frame 21, and the button 251 can slide along the central axis direction of the fifth pins 254. The third elastic member 255 is sleeved on the fifth pin 254, and the third elastic member 255 provides an elastic force to the button 251 to move the button 251 toward the fourth penetrating opening 217. Further, a fourth incline 2513 is provided on the side of the button 251 facing away from the latch structure 24. The button 251 correspondingly penetrates through the fourth penetrating opening 217.

As shown in fig. 14, the auxiliary restoring element 252 is provided with sliding lugs 2521 on both sides, and correspondingly, the main frame 21 is provided with sliding grooves (not shown) corresponding to the sliding lugs 2521, and the sliding lugs 2521 are slidably mounted in the sliding grooves. The side edge of the auxiliary reset element 252 facing the hook structure 24 abuts against the fourth inclined surface 2513, and a second elastic element 253 is installed between the side edge of the auxiliary reset element 252 facing away from the hook structure 24 and the cavity wall of the assembly space. When the button 251 is pressed, the fourth inclined surface 2513 pushes the auxiliary reset element 252 towards one side edge of the hook structure 24, so that the auxiliary reset element 252 moves away from the hook structure 24, and the second elastic element 253 is further compressed; when the button 251 is released, the second elastic member 253 provides an elastic force to the auxiliary restoring member 252, so that the auxiliary restoring member 252 pushes the fourth inclined surface 2513 toward one side of the hook structure 24, thereby moving the button 251 toward the fourth penetrating port 217.

And, when the barbed end 2411 is turned out of the fitting space from the third through-outlet 216 to the outside, the third inclined surface 2422 of the auxiliary unlocking piece 242 abuts on the side of the button 251 away from the fourth through-outlet 217 at this time. When the button 251 is pressed, one side edge of the button 251 away from the fourth through-outlet 217 slides along the third inclined surface 2422 and pushes the third inclined surface 2422, so that the auxiliary unlocking piece 242 moves towards the position close to the third through-outlet 216, that is, the first inclined surface 2414 and the second inclined surface 2421 slide towards each other, and then the first inclined surface 2414 pushes the second inclined surface 2421 to gradually disengage the auxiliary unlocking piece 242 from the matching groove 2412.

In the spliced magic cube board of the present application, as shown in fig. 4, the hook inserting structures 24 are provided in four, the unlocking structures 25 are also provided in four, and the four unlocking structures 25 and the four hook inserting structures 24 are provided in one-to-one correspondence. That is, the main frame 21 is defined by a central position, and one engagement structure 23, two latch structures 24, and two unlocking structures 25 are symmetrically provided on both sides of the defined position. Taking the right side of the boundary as an example, the connecting line direction between the two hook inserting structures 24 and the connecting line direction between the two unlocking structures 25 are both the thickness direction of the magic square plate. Accordingly, two fourth through-holes 217 are provided on both sides of the main frame 21 in the thickness direction, respectively.

As shown in fig. 3, after the user completes the flat splice of two pieces of the spliced cube boards, the user may use the third piece of the spliced cube board to perform the vertical splice, that is, the surface of the third piece of the cube board is perpendicular to the extension surface formed by the flat splice of the first two pieces of the cube boards. In addition, the first two magic cube boards can be spliced without flattening, and only two magic cube boards are required to be placed in a flattening manner, so that two opposite frame assemblies 20 between the two magic cube boards are placed relatively and in contact, and then a third magic cube board is adopted for vertical splicing on the two magic cube boards placed in a flattening manner, so that a lattice cabinet is formed.

Specifically, the barb ends 2411 of the four hook members 241 of one of the frame assemblies 20 of the third spliced magic cube board are all turned out to the outside, and at this time, the four barb ends 2411 of the third magic cube board can be in one-to-one correspondence with the four fourth penetrating openings 217 on the same side of the first and second magic cube boards that have been flattened and spliced together. And the four barb ends 2411 of the third magic cube plate are inserted into the four fourth penetrating outlets 217 of the first and second magic cube plates in a one-to-one correspondence, so that the barb ends 2411 of the third magic cube push down the four buttons 251 of the first and second magic cubes. Then hearing the "snap" sound, each barb end 2411 of the third cube plate passes over the corresponding auxiliary reset piece 252 of the first and second cube plates and hooks on the corresponding side edge of the auxiliary reset piece 252, thereby restricting the barb end 2411 of the third cube plate from falling out of the fourth through-hole 217 of the first and second cube plates, and at this time, the third cube plate is firmly and vertically spliced on the first and second flattened cube plates.

When a user needs to detach the vertically spliced third cube-shaped plate from the first and second flat spliced cube-shaped plates, the user only needs to press the four buttons 251 of the third cube-shaped plate, and then pulls out the barb ends 2411 of the third cube-shaped plate from the fourth penetrating openings 217 of the first and second cube-shaped plates with force, so that the third cube-shaped plate can be detached. Specifically, in the process that the user presses the button 251 of the third magic cube, the button 251 is away from one side of the fourth through-hole 217, that is, pushes the third inclined surface 2422 of the auxiliary unlocking member 242, so that the second inclined surface 2421 of the auxiliary unlocking member 242 moves towards being close to the first inclined surface 2414. During the sliding process of the second inclined plane 2421 along the first inclined plane 2414, the first inclined plane 2414 pushes the second inclined plane 2421, so that the auxiliary unlocking piece 242 is separated from the matching groove 2412 and abuts against one side edge of the corresponding auxiliary reset piece 252 in the first and second magic cube panels, and thus the corresponding auxiliary reset piece 252 of the first and second magic cube panels is extruded so as to be separated from the barb end 2411 of the third magic cube panel. Then, the user holds the button 251 and pulls the third cube, so that the barbed ends 2411 are separated from the fourth through-holes 217 of the first and second cube. In the process that the barb end 2411 of the third cube board is separated from the fourth through-hole 217 of the first and second cube boards, the end portion of the auxiliary unlocking piece 242 of the third cube board, on which the second inclined surface 2421 is arranged, exceeds the barb end 2411 and abuts against the corresponding buttons 251 of the first and second cube boards, so that the corresponding buttons 251 of the first and second cube boards move together with the end portion of the auxiliary unlocking piece 242 of the third cube board under the action of the elasticity of the third elastic piece 255. In the process that the end of the auxiliary unlocking piece 242 of the third magic cube plate passes over the corresponding auxiliary resetting piece 252 of the first and second magic cube plates, the buttons 251 of the first and second magic cube plates also pass over the corresponding auxiliary resetting piece 252. Then, each barb end 2411 of the third cube board is completely separated from the corresponding fourth penetrating opening 217 of the first and second cube boards, in the first and second cube boards, after the end of the button 251 along with the auxiliary unlocking piece 242 of the third cube board passes over the corresponding auxiliary resetting piece 252, the side edge of the auxiliary resetting piece 252 abuts against the fourth inclined surface 2513 of the button 251, and moves towards the position close to the hook inserting structure 24 under the action of the elastic force of the second elastic piece 253, so that relative sliding is generated between the side edge of the auxiliary resetting piece 252 and the fourth inclined surface 2513, the side edge of the auxiliary resetting piece 252 pushes the fourth inclined surface 2513, so that the button 251 moves towards the fourth penetrating opening 217, and finally the button 251 moves out to the fourth penetrating opening 217 to realize resetting.

Through the polylith concatenation magic cube board that uses this application to provide, not only can carry out the flattening concatenation and form bigger surface to the adaptation tiling is on the desktop, or the adaptation is laid on the wall, but also can carry out the perpendicular concatenation, thereby the combination forms the check cabinet and supplies the user to put article. Because the concatenation magic cube board that this application provided carries out the flat concatenation to two adjacent magic cube boards through buckling structure 23 to mutually support through inserting hook structure 24 and unblock structure 25 and splice the magic cube board perpendicularly, realized convenient, swift dismouting's purpose, the user can recycle this concatenation magic cube board moreover, convenient and practical.

The foregoing description of the preferred embodiments of the present application is not intended to be limiting, but is intended to cover any and all modifications, equivalents, and alternatives falling within the spirit and principles of the present application.

Claims (10)

1. A spliced magic cube board, comprising:

a substrate;

the frame components are fixed on the periphery of the substrate in a surrounding mode; wherein,,

each frame component comprises a main frame body, a cover body, at least one inserting hook structure and at least one unlocking structure, wherein the cover body is covered on the main frame body to form an assembling space, the inserting hook structure and the unlocking structure are both arranged in the assembling space, the main frame body is provided with a third penetrating opening and a fourth penetrating opening which are communicated with the assembling space, the inserting hook structure comprises a hook body piece, an auxiliary unlocking piece and a first elastic piece, the hook body piece is provided with a barb end, the hook body piece is rotatably arranged in the main frame body, the barb end can be rotated out of or rotated into the assembling space from the third penetrating opening, the hook body piece is provided with a matching groove, the position of the groove bottom of the matching groove, which is close to the barb end, is set to be a first inclined plane, one side groove wall of the matching groove is provided with a second avoiding opening, two ends of the auxiliary unlocking piece are respectively provided with a second inclined plane and a third inclined plane, the side wall of the auxiliary unlocking piece is provided with a reset protrusion, the auxiliary unlocking piece is arranged in the matching groove and the reset protrusion is positioned in the second avoidance port, the first elastic piece is arranged between the side wall of the reset protrusion facing the barb end and the side wall of the avoidance port, the first inclined surface and the second inclined surface can slide relatively, the unlocking structure comprises a button, an auxiliary resetting piece, a second elastic piece and a third elastic piece, the button is slidably arranged in the main frame body, the second elastic piece is used for providing an elastic force for the button to enable the button to move towards the fourth through-hole, the side edge of the button deviating from the fourth through-hole is abutted to the third inclined surface when the barb end rotates out of the third through-hole, the auxiliary resetting piece is slidably arranged in the main frame body, the third elastic member is installed between the auxiliary restoring member and the main frame body to apply an elastic force to the auxiliary restoring member to move the auxiliary restoring member toward the hook structure.

2. The spliced magic cube panel according to claim 1, characterized in that,

the unlocking structure further comprises a fifth pin shaft, the button is installed in the assembly space through the fifth pin shaft, the button can slide back and forth along the central axis direction of the fifth pin shaft, and the second elastic piece is sleeved on the fifth pin shaft and provides elastic force for the button to enable the button to move towards the fourth penetrating opening.

3. The spliced magic cube panel according to claim 1 or 2, characterized in that,

the button deviates from the one side of inserting the hook structure is equipped with the fourth inclined plane, supplementary reset piece orientation insert the side of hook structure can with the fourth inclined plane butt and relative slip.

4. The spliced magic cube panel according to claim 1, characterized in that,

each frame component further comprises at least one buckling structure, the buckling structures are installed in the assembly space, the main frame body is further provided with a first penetrating opening and a second penetrating opening which are communicated with the assembly space, each buckling structure comprises a sliding pushing piece and a clasp piece, a sliding pushing operation end of each sliding pushing piece penetrates out of the corresponding first penetrating opening and can slide along the extending direction of the corresponding first penetrating opening, each clasp piece is provided with an arc sliding hole and a clasp part, the sliding pushing pieces are connected with the corresponding arc sliding holes through first pin shafts, the first pin shafts can move along the corresponding arc sliding holes, and each clasp piece is rotatably installed in the main frame body and extends to the corresponding second penetrating opening.

5. The spliced magic cube panel of claim 4,

the buckling structure further comprises a connecting rod and a pushing piece, two ends of the connecting rod are respectively connected with the clasp piece and the pushing piece in a rotating mode, the connecting rod is installed in the main frame body in a rotating mode, the pushing piece is installed in the main frame body in a sliding mode, the clasp piece drives the pushing piece to reciprocate along the connecting line direction between the pushing piece and the second penetrating opening through the connecting rod, and the pushing piece faces to the end face of the second penetrating opening and is arranged at intervals on the clasp portion.

6. The spliced magic cube panel of claim 5,

the buckling structure further comprises a limiting piece, the limiting piece forms a C-shaped space, a first avoidance opening is formed in the limiting piece, the connecting rod is provided with a limiting protrusion, the limiting protrusion is arranged in the C-shaped space and corresponds to the first avoidance opening, the limiting piece is fixedly mounted to the main frame body, the limiting piece is provided with a propping end face, the propping end face faces the clasp part and the pushing piece, and the propping end face is used for propping against the limiting clasp part and the pushing piece when the clasp part is in a buckling state.

7. The spliced magic cube panel according to any of claims 4-6,

the clasp piece is also provided with a first rotating hole, the clasp piece is rotatably installed in the main frame body through the cooperation of the first rotating hole and the second pin shaft, the first rotating hole is a strip-shaped through hole, and the extending direction of the first rotating hole is consistent with the extending direction of the first penetrating hole.

8. The spliced magic cube panel according to claim 5 or 6, characterized in that,

the pushing piece is provided with a pushing connecting hole, the pushing piece is connected to one end of the connecting rod through the pushing connecting hole matched with a third pin shaft, the pushing connecting hole is provided with a strip-shaped through hole, and the extending direction of the pushing connecting hole is consistent with the extending direction of the first penetrating opening.

9. The spliced magic cube panel according to claim 5 or 6, characterized in that,

the pushing piece is provided with a guide lug, the cavity wall of the assembly space of the main frame body is provided with a guide groove, the guide lug is inserted into the guide groove, and the guide lug can slide back and forth along the guide groove.

10. The spliced magic cube panel according to any of claims 4-6,

the cover body is provided with a clamping protrusion, the main frame body is provided with a clamping groove, and the clamping protrusion is positioned and clamped in the clamping groove;

and/or one side of the main frame body, which faces the substrate, is provided with a positioning protrusion and an inserting block, and the side edge of the substrate is provided with a positioning groove matched with the positioning protrusion and an inserting groove matched with the inserting block.

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