Magnetic type gyroscope with modular combination
By combining modular design with magnetic snap-fit connection, the problem of insufficient magnetic attraction in traditional gyroscopes is solved, achieving stability and diverse combinations of gyroscopes and improving user experience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANTOU WANYI TECHNOLOGY CO LTD
- Filing Date
- 2025-08-12
- Publication Date
- 2026-06-05
AI Technical Summary
The uneven distribution of magnetic field lines in traditional magnetic gyroscopes leads to a decrease in magnetic attraction, affecting the stability of the module and the overall structure.
It adopts a modular design, including a main module, a central connecting block, a sub-module, and a transfer connecting part. It uses a combination of magnetic attraction and snap-fit connection, and utilizes a cubic structure and interference fit to enhance magnetic attraction and connection stability.
It achieves modular combination and flexible and convenient magnetic connection, enhancing the fun and creativity of the gyroscope and meeting users' needs for entertainment and creative expression.
Smart Images

Figure CN224327734U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to gyroscopes, specifically to a magnetically attached gyroscope with modular assembly. Background Technology
[0002] In the traditional design of the magnetic chuck of a gyroscope, the method of embedding square magnetic beads in the four corners has obvious drawbacks. Due to the limitation of the shape of the square magnetic beads, there are blind spots in the distribution of magnetic field lines in the non-diagonal directions. In addition, since the magnetic beads are completely built into the shell, magnetic loss will inevitably occur when the magnetic force penetrates the shell material of a certain thickness.
[0003] Since the magnet is located inside the shell and no auxiliary through-hole structure is provided, the certain wall thickness of the shell further weakens the magnetic field strength generated by the magnetic bead, resulting in a significant decrease in the magnetic attraction between the magnetic ends.
[0004] This design flaw makes the sub-modules prone to falling off during rotation. These design defects, when combined, not only weaken the magnetic attraction between the modules but also greatly affect the overall stability of the gyroscope structure.
[0005] Therefore, it is necessary to improve the traditional magnetic gyroscope. Utility Model Content
[0006] The purpose of this invention is to provide a magnetically attached gyroscope with modular assembly to solve the problems mentioned in the background art.
[0007] To solve the above-mentioned technical problems, this utility model achieves the following solution: A modularly assembled magnetic gyroscope of this utility model includes:
[0008] The main module has two splicing blocks arranged back to back and connected together by an axis, and a central connecting block rotatably disposed between the two splicing blocks, the central connecting block being able to rotate around an axis;
[0009] The transfer connection part is provided in two sets, and the inner ends of the two sets of transfer connection parts are snapped one-to-one with the outer ends of the two splicing blocks;
[0010] The sub-module has each face that can be magnetically connected to each rotating face of the central connecting block, and each face of the sub-module can also be magnetically connected to the outer end face of the transfer connecting part.
[0011] Furthermore, the ends of the first connecting shafts on the two splicing blocks are joined together to form an interference fit connection structure.
[0012] Furthermore, the central connecting block has a cubic structure;
[0013] The central connecting block has a first circular cavity in each of its eight corners, and a first through hole in each of its four corners. Each first circular cavity is connected to three nearby first through holes.
[0014] Each first circular cavity is equipped with a first magnetic bead.
[0015] Furthermore, the splicing block has a flat surface that contacts the central connecting block, and its first snap-fit surface that connects to the transfer connecting part is provided with two slots and two protrusions.
[0016] The two card slots are located at the first diagonal ends of the first card contact surface;
[0017] Two protruding buckles are located at the second diagonal ends of the first snap-fit surface, and the inner contour of the slot and the outer contour of the protruding buckles can be interference-fitted.
[0018] Furthermore, the transfer connection includes:
[0019] A first component that snaps into the splicing block, wherein the second snapping surface of the first component has the same structure as the first snapping surface of the splicing block;
[0020] The second component is axially connected to the first component. Each of the four corners of the outer end of the second component is provided with a second circular cavity. Each of the three adjacent surfaces of the second circular cavity is connected to a second through hole.
[0021] Each second circular cavity is equipped with a second magnetic bead.
[0022] Furthermore, the sub-module has a cubic structure.
[0023] Furthermore, each surface of the sub-module is a sunken groove structure.
[0024] Furthermore, each of the eight corners of the sub-module is provided with a third circular cavity, and each of the four corners of each face is provided with a third through hole, and each third circular cavity is connected to three nearby third through holes.
[0025] Each third cavity is equipped with a third magnetic bead.
[0026] Compared with the prior art, the beneficial effects of this utility model are:
[0027] 1. This utility model achieves modular combination of gyroscope by setting up a main module, a transfer connection part and a sub-module.
[0028] 2. This utility model adopts a connection method that combines magnetic attraction and snap-fit. The interference fit of the snap-fit part ensures the structural stability of the connection, while the magnetic attraction part makes the connection and disassembly between modules more flexible and convenient.
[0029] 3. The central connecting block, the second component of the transfer connecting part, and the sub-module of the cubic structure of this utility model can achieve diverse combination forms. Users can assemble different shapes according to their own preferences and creativity, which greatly enhances the fun and creativity of the gyroscope and meets the needs of different users in terms of entertainment and creative expression. Attached Figure Description
[0030] Figure 1 This is a structural diagram of the magnetic gyroscope of this utility model.
[0031] Figure 2 This is a structural diagram of the main module of this utility model.
[0032] Figure 3 This is an exploded view of the main module of this utility model.
[0033] Figure 4 This is a structural diagram of the transfer connection part of this utility model.
[0034] Figure 5 This is an exploded view of the transfer connection part of this utility model.
[0035] Figure 6 This is a structural diagram of the sub-module of this utility model.
[0036] Figure 7 This is an exploded view of the sub-module of this utility model.
[0037] The attached diagram is labeled as follows: Sub-module-1, Transfer connection-2, Main module-3, Intermediate block-11, Third through hole-12, Third circular cavity-13, End cap-14, First component-21, Second component-22, Central connecting block-31, Splicing block-32, First circular cavity-33, Second circular cavity-221, T-shaped column-222, Second connecting shaft-223, Second through hole-224, Square side cover-225, Intermediate square block-311, Side cover-312, Protruding buckle-321, Slot-322, First connecting shaft-323, First through hole-3121. Detailed Implementation
[0038] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments, so that the advantages and features of the present utility model can be more easily understood by those skilled in the art, thereby making a clearer and more definite definition of the protection scope of the present utility model. Obviously, the embodiments described in this utility model are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of the present utility model.
[0039] Furthermore, the technical features involved in the different embodiments of this utility model described below can be combined with each other as long as they do not conflict with each other.
[0040] Example 1: The specific structure of this utility model is as follows:
[0041] Please refer to the appendix. Figure 1-7 The present invention provides a modular magnetic gyroscope, comprising a main module 3, a transfer connection 2, and a sub-module 1.
[0042] The main module 3 has two splicing blocks 32 arranged back to back and connected together by an axis, and a central connecting block 31 rotatably disposed between the two splicing blocks 32. The central connecting block 31 can rotate around an axis.
[0043] The ends of the first connecting shafts 323 on the two splicing blocks 32 are joined together to form an interference fit connection structure, such as Figure 3 As shown, the first connecting shaft 323 on the two splicing blocks 32 is divided into a socket end and an insertion end, with the insertion end able to be inserted into the socket end to achieve an interference fit. The first connecting shaft 323 serves as a shaft structure, providing rotational support. The central connecting block 31 is fitted onto the first connecting shaft 323 and can rotate.
[0044] The central connecting block 31 has a cubic structure, with a first circular cavity 33 in each of its eight corners and a first through hole 3121 at each of the four corners of each face. Each first circular cavity 33 is connected to three nearby first through holes 3121. Each first circular cavity 33 contains a first magnetic bead. After the first magnetic bead is inserted into the first circular cavity 33, part of the spherical surface of the first magnetic bead can protrude from the first through hole 3121 and be flush with the opening. Since the first magnetic bead can directly attract other magnetic beads, the magnetic attraction force is strengthened, making the magnetic attraction between the central connecting block 31 and the sub-module 1 stable.
[0045] Specifically, the central connecting block 31 includes a central block 311 and side covers 312 with the same structure at both ends. The central block 311 has a through cavity that passes through both ends, and its corners are thickened. A connecting hole that passes through both ends is provided at the thickened part, and the two ends of each connecting hole are first hemispherical groove surfaces.
[0046] The side cover 312 is connected to the central connecting block 311 by mortise and tenon joints. The four corners of the connecting surface are provided with second hemispherical grooves. The first hemispherical groove and the second hemispherical groove combine to form the first circular cavity 33.
[0047] The splicing block 32 has a flat surface that connects with the central connecting block 31. The first snap-fit surface that connects with the transfer connecting part 2 has two slots 322 and two protrusions 321. The end faces of the slots 322 and the protrusions 321 are flat, and the depth of the slots 322 is greater than or equal to the height of the protrusions 321.
[0048] The two card slots 322 are located at the first diagonal ends of the first card contact surface;
[0049] Two protrusions 321 are located at the second diagonal ends of the first snap-fit surface, and the inner contour of the slot 322 and the outer contour of the protrusion 321 can be interference-fitted.
[0050] like Figure 4-5 As shown, the transfer connection part 2 is provided in two sets, and the inner ends of the two sets of transfer connection parts 2 are connected one-to-one with the outer ends of the two splicing blocks 32.
[0051] The transfer connection part 2 includes:
[0052] The first component 21, which is engaged with the splicing block 32, has a second engaging surface that has the same structure as the first engaging surface of the splicing block 32, such as... Figure 4 and Figure 3 As shown, the protrusion on the first component 21 is inserted into the slot 322 on the splicing block 32, and the protrusion on the splicing block 32 is inserted into the slot on the first component 21, thereby connecting the first component 21 and the splicing block 32.
[0053] The second component 22 is axially connected to the first component 21. Each of the four corners of the outer end of the second component 22 is provided with a second circular cavity 221. Each of the three adjacent surfaces of the second circular cavity 221 is connected to a second through hole 224.
[0054] Each second circular cavity 221 is provided with a second magnetic bead.
[0055] Specifically, the first component 21 has a second connecting shaft 223, and a T-shaped post 222 is inserted into the outer end of the second connecting shaft 223. The second component 22 includes a square bottom cover and a square side cover 225. The four corners of the square bottom cover are provided with a third hemispherical groove surface, and the four corners of the cover surface of the square side cover are provided with a fourth hemispherical groove surface. The third hemispherical groove surface and the fourth hemispherical groove surface are closed to form the second circular cavity 221. The square side cover 225 has a circular hole in the middle, and after the T-shaped post 222 is fixed, its disc mates with the circular hole.
[0056] like Figure 6-7 As shown, each surface of the sub-module 1 can be magnetically connected to each rotating surface of the central connecting block 31, and each surface of the sub-module 1 can also be magnetically connected to the outer end surface of the transfer connecting part 2.
[0057] Specifically, the sub-module 1 has a cubic structure with each face being a sunken groove structure. The sunken grooves are used for stickers to enrich the appearance of the sub-module 1.
[0058] Each of the eight corners of the sub-module 1 is provided with a third circular cavity 13, and each of the four corners of each face is provided with a third through hole 12. Each third circular cavity 13 is connected to three nearby third through holes 12; each third circular cavity 13 is provided with a third magnetic bead.
[0059] like Figure 7 As shown, the sub-module 1 includes a middle block 11 and two identical end caps 14, which are mortised and tenoned together with the middle block 11. The middle block 11 has a fifth hemispherical groove at each of its four corners, and the end caps 14 have a sixth hemispherical groove at each of their four corners. The fifth and sixth hemispherical grooves together form the third circular cavity 13.
[0060] like Figure 1 As shown, sub-module 1 is connected to the central connecting block 31 via a third magnetic bead magnetically attracted to the first magnetic bead. Multiple sub-modules 1 are connected via the third magnetic bead magnetically attracted to each other. The third magnetic bead magnetically attracts the second magnetic bead, thus achieving a magnetic connection between the sub-module 1 and the transfer connecting part 2.
[0061] Example 2:
[0062] The main module 3, sub-module 1, and transfer connection part 2 of this utility model can also be applied to building block toys, and different toy shapes can be built by magnetic attraction.
[0063] In summary, this utility model achieves modular combination of gyroscopes by setting up a main module, a relay connection part and a sub-module.
[0064] This utility model adopts a connection method that combines magnetic attraction and snap-fit. The interference fit of the snap-fit part ensures the structural stability of the connection, while the magnetic attraction part makes the connection and disassembly between modules more flexible and convenient.
[0065] The central connecting block, the second component of the transfer connecting part, and the sub-module of the cubic structure of this utility model can achieve diverse combination forms. Users can splice different shapes according to their own preferences and creativity, which greatly enhances the fun and creativity of the gyroscope and meets the needs of different users in terms of entertainment and creative expression.
[0066] The above description is only a preferred embodiment of the present utility model and does not limit the patent scope of the present utility model. Any equivalent structural or procedural transformations made based on the contents of the present utility model specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of the present utility model.
Claims
1. A magnetically attached gyroscope with modular assembly, characterized in that, include: The main module (3) has two splicing blocks (32) arranged back to back and connected together by an axis, and a central connecting block (31) rotatably disposed between the two splicing blocks (32), the central connecting block (31) being able to rotate around an axis; The transfer connection part (2) is provided in two sets, and the inner ends of the two sets of transfer connection parts (2) are connected one-to-one with the outer ends of the two splicing blocks (32); Sub-module (1), each surface of which can be magnetically connected to each rotating surface of the central connecting block (31), and each surface of which can also be magnetically connected to the outer end face of the transfer connecting part (2).
2. The magnetically attached gyroscope with modular assembly according to claim 1, characterized in that, The ends of the first connecting shafts (323) on the two splicing blocks (32) are joined together to form an interference fit connection structure.
3. The magnetically attached gyroscope with modular assembly according to claim 1, characterized in that, The central connecting block (31) has a cubic structure; The central connecting block (31) has a first circular cavity (33) in each of its eight corners, and a first through hole (3121) is provided at each of the four corners of each of its surfaces. Each first circular cavity (33) is connected to three nearby first through holes (3121). Each first circular cavity (33) is provided with a first magnetic bead.
4. The magnetically attached gyroscope with modular assembly according to claim 1, characterized in that, The splicing block (32) has a flat surface that connects with the central connecting block (31), and its first snap-fit surface that connects with the transfer connecting part (2) is provided with two slots (322) and two protrusions (321). The two card slots (322) are located at the first diagonal ends of the first card contact surface; Two protruding buckles (321) are located at the second diagonal ends of the first snap-fit surface, and the inner contour of the snap-fit groove (322) and the outer contour of the protruding buckle (321) can be interference-fitted.
5. A magnetically attached gyroscope with modular assembly according to claim 4, characterized in that, The transfer connection part (2) includes: The first component (21) that snaps into the splicing block (32) has the same structure as the first snap-in surface of the splicing block (32) on its second snap-in surface. The second component (22) is axially connected to the first component (21). The four corners of the outer end of the second component (22) are provided with second circular cavities (221). Each second circular cavity (221) has a second through hole (224) connected to the three sides of the two adjacent surfaces. Each second circular cavity (221) is provided with a second magnetic bead.
6. The magnetically attached gyroscope with modular assembly according to claim 1, characterized in that, The sub-module (1) has a cubic structure.
7. A magnetically attached gyroscope with modular assembly according to claim 6, characterized in that, Each surface of the sub-module (1) is a sunken groove structure.
8. A magnetically attached gyroscope with modular assembly according to claim 6, characterized in that, The sub-module (1) has a third circular cavity (13) in each of its eight corners, and a third through hole (12) in each of its four corners. Each third circular cavity (13) is connected to three nearby third through holes (12). Each third circular cavity (13) is provided with a third magnetic bead.