Flywheel structural member having a segmental hand

By using a magnetic ring rotor and permanent magnet design, the problems of complex and high cost of existing mouse scroll wheel structures are solved, achieving a simple, low-cost and stable tactile experience.

CN224383665UActive Publication Date: 2026-06-19DONGGUAN CITY KAIHUA ELECTRONICS

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DONGGUAN CITY KAIHUA ELECTRONICS
Filing Date
2025-04-24
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Existing mouse scroll wheels have complex structures, and the use of permanent magnets and electromagnets results in high costs and limited lifespans, making it difficult to provide a stable tactile feedback experience.

Method used

The design uses a ring rotor and permanent magnet made of magnetic material. The segmented feel is achieved through magnetic interference between the permanent magnet and the ring rotor, avoiding the use of electromagnetic components. The structure is simple and the cost is low.

Benefits of technology

It provides a stable tactile feedback experience, reduces production costs, extends product lifespan, and simplifies structural design.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a flywheel structure with a segmented tactile feel, including a flywheel bracket, a flywheel body rotatably disposed within the flywheel bracket, an annular rotor disposed on the inner wall of the flywheel body, and at least one permanent magnet disposed on the side of the flywheel bracket, spaced apart from the flywheel body and directly opposite the annular rotor. Several first protruding magnetic attraction portions are formed on the outer side of the annular rotor, arranged at intervals. The permanent magnet magnetically attracts the annular rotor. This utility model eliminates the need for electromagnetic components; the magnetic attraction of the permanent magnet to the annular rotor creates a distinct segmented feel during free rotation of the flywheel, effectively avoiding the performance and lifespan limitations caused by electronic components. Furthermore, this flywheel structure is simple in structure, low in production cost, and effectively meets the development needs of modern production.
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Description

Technical Field

[0001] This utility model relates to the field of input technology, and in particular to a flywheel structure with segmented tactile feedback. Background Technology

[0002] As an important component of the mouse, the performance and user experience of the mouse wheel have a significant impact on the overall evaluation of the mouse.

[0003] Most existing undamped scroll wheels are grating scroll wheels, which count by blocking light through a wheel with spokes. These spokes are also the source of the scroll wheel's tactile feedback. Simply use a small wire to hold the spokes in place; as the scroll rotates, it scrapes against the wire, creating the tactile feedback. When the button is pressed, a small lever can push the wire away, disengaging it from the spokes, allowing the spokes to roll freely.

[0004] Over time, the internal structure of such rollers experiences wear. Therefore, rollers utilizing the properties of electromagnets have been developed. The inner ring of the roller is lined with a ferromagnetic material, and inside the roller is a pair of magnets, one permanent magnet and the other an electromagnet. When energized, the electromagnet's magnetic field strength is similar to that of the permanent magnet, but its polarity can be adjusted by controlling the direction of the current. In segmented scrolling mode, the electromagnet and permanent magnet have the same polarity, effectively acting as a single large magnet. At both ends of the electromagnet and permanent magnet are small pieces of ferromagnetic material with a spiked structure similar to the inner ring of the roller. When these two spikes approach each other, the magnetic force creates a segmented feel. When switching to undamped mode, the current in the electromagnet reverses direction, and the polarity of the electromagnet and permanent magnet becomes opposite. In this mode, the magnetic field lines are confined to the roller core, exerting no magnetic force on the outer ferromagnetic ring, allowing the outer ring to roll freely.

[0005] However, existing technologies involve permanent magnets and electromagnets, resulting in exceptionally complex internal structures, high component and manufacturing costs, and the lifespan of electronic components that can significantly impact the overall performance and lifespan of the product. Therefore, this invention focuses on simplifying components and designing a novel structure to ensure the flywheel provides a satisfying tactile feedback during rotation, while simultaneously reducing costs and increasing product lifespan. Utility Model Content

[0006] To address the aforementioned shortcomings, the purpose of this utility model is to provide a flywheel structure with a segmented tactile feel. It does not require the use of electromagnetic components; instead, it utilizes the magnetic attraction of a permanent magnet to the annular rotor to create a distinct segmented feel during the flywheel's free rotation. This effectively avoids the performance and lifespan limitations caused by electronic components. Furthermore, this flywheel structure is simple in structure and has a low production cost, effectively meeting the development needs of modern production.

[0007] The technical solution adopted by this utility model to achieve the above objectives is as follows:

[0008] A flywheel structure with segmented tactile feedback includes a bracket, a flywheel body rotatably mounted on the bracket, and an annular rotor mounted on the flywheel body. The annular rotor is made of a magnetic material, and its outer ring wall is provided with grooves at intervals. At least one permanent magnet is provided on the bracket that is opposite to and non-contact with the grooves of the annular rotor, and the permanent magnet performs magnetic interference on the annular rotor.

[0009] As a further improvement of this utility model, the height of the permanent magnet is greater than the outer perimeter of the groove opening.

[0010] As a further improvement of this utility model, the number of permanent magnets is two sets, and the two sets of permanent magnets are symmetrically arranged on both sides of the flywheel bracket. They are a first permanent magnet arranged on the left side of the flywheel bracket and a second permanent magnet arranged on the right side of the flywheel bracket.

[0011] As a further improvement of this utility model, a first embedding groove for inserting the first permanent magnet and a second embedding groove symmetrical to the first embedding groove for inserting the second permanent magnet are respectively formed on the side of the flywheel bracket.

[0012] As a further improvement of this utility model, it also includes a first baffle plate covering the first embedding groove and limiting the upper end of the first permanent magnet, and a second baffle plate covering the second embedding groove and limiting the upper end of the second permanent magnet.

[0013] As a further improvement of this utility model, the first baffle includes a first upper limit plate covering the first embedding groove and limiting the upper end of the first permanent magnet, and a first lower limit plate symmetrically disposed on both sides of the lower end face of the first upper limit plate; the second baffle includes a second upper limit plate covering the second embedding groove and limiting the upper end of the second permanent magnet, and a second lower limit plate symmetrically disposed on both sides of the lower end face of the second upper limit plate.

[0014] As a further improvement of this utility model, first lower limiting grooves for inserting the first lower limiting piece are formed on both sides of the first embedding groove. A first engaging flange protrudes from the inner wall of the first lower limiting groove near the first embedding groove. A first engaging groove for engaging the first engaging flange is formed in the middle of the first lower limiting piece. Second lower limiting grooves for inserting the second lower limiting piece are formed on both sides of the second embedding groove. A second engaging flange protrudes from the inner wall of the second lower limiting groove near the second embedding groove. A second engaging groove for engaging the second engaging flange is formed in the middle of the second lower limiting piece.

[0015] As a further improvement of this utility model, the lower side of the first lower limiting piece is provided with a first inclined guide surface extending from the upper outer direction to the lower inner direction; the lower side of the second lower limiting piece is provided with a second inclined guide surface extending from the upper outer direction to the lower inner direction.

[0016] As a further improvement of this utility model, a third inclined guide surface is formed on the upper end surface of the first snap-fit ​​flange, extending inclinedly from the upper part of the first embedding groove toward the lower part of the first snap-fit ​​groove; a fourth inclined guide surface is formed on the upper end surface of the second snap-fit ​​flange, extending inclinedly from the upper part of the second embedding groove toward the lower part of the second snap-fit ​​groove.

[0017] The beneficial effects of this utility model are as follows:

[0018] This flywheel structure, designed to provide a tactile, segmented feel, includes a support frame and a flywheel body rotatably mounted on the support frame. Its key feature is the inclusion of an annular rotor mounted on the flywheel body. The annular rotor is made of a magnetic material, and its outer ring wall is spaced with grooves. At least one permanent magnet, opposite to but not in contact with the grooves on the annular rotor, is mounted on the support frame. The permanent magnets magnetically interfere with and magnetically attract the annular rotor. When the flywheel body rotates, the annular rotor rotates synchronously. When the rotor is directly opposite the permanent magnet (without a groove), the attraction force is strong; when it is directly opposite the groove, the attraction force is weaker. This segmented design creates a distinct tactile feel, improving the user experience. Furthermore, it eliminates the need for electromagnetic components, effectively avoiding the performance and lifespan limitations caused by electronic components. The flywheel structure is also simple in structure, low in production cost, and effectively meets the needs of modern manufacturing.

[0019] The above is an overview of the utility model's technical solution. The following description, in conjunction with the accompanying drawings and specific embodiments, will further illustrate the utility model. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the overall design of this utility model;

[0021] Figure 2 This is an exploded view of the present invention;

[0022] Figure 3 This is a schematic diagram of the support structure;

[0023] Figure 4 A cross-sectional view of the first and second baffles mounted on the bracket;

[0024] Figure 5 This is a cross-sectional view of the flywheel body of this utility model;

[0025] In the figure: 1. Bracket; 11. First embedding groove; 12. Second embedding groove; 13. First lower limit groove; 14. First snap-fit ​​flange; 141. Third inclined guide surface; 15. Second lower limit groove; 16. Second snap-fit ​​flange; 161. Fourth inclined guide surface; 2. Flywheel body; 3. Annular rotor; 31. Groove; 4. First permanent magnet; 5. Second permanent magnet; 6. First baffle; 61. First upper limit plate; 62. First lower limit plate; 621. First snap-fit ​​groove; 622. First inclined guide surface; 7. Second baffle; 71. Second upper limit plate; 72. Second lower limit plate; 721. Second snap-fit ​​groove; 722. Second inclined guide surface. Detailed Implementation

[0026] To further illustrate the technical means and effects adopted by this utility model to achieve its intended purpose, the specific implementation methods of this utility model will be described in detail below with reference to the accompanying drawings and preferred embodiments.

[0027] In the description of this utility model, it should be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.

[0028] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this utility model, "a plurality of" means two or more, unless otherwise explicitly specified.

[0029] In this utility model, unless otherwise explicitly specified and limited, the terms "installation," "connection," "joining," and "fixing," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model according to the specific circumstances.

[0030] Please refer to Figures 1 to 5 This utility model embodiment provides a flywheel structure with segmented tactile feedback, including a bracket 1, a flywheel body 2 rotatably mounted on the bracket 1, and an annular rotor 3 mounted on the flywheel body 2. The annular rotor 3 is made of a magnetic material, and the outer ring wall of the annular rotor 3 is provided with grooves 31 at intervals. At least one permanent magnet (4, 5) is provided on the bracket 1 that is opposite to and non-contact with the grooves 31 of the annular rotor 3, and the permanent magnet (4, 5) performs magnetic interference on the annular rotor 3.

[0031] The permanent magnets (4, 5) magnetically attract the annular rotor 3. When the flywheel body 2 rotates, the annular rotor 3 is driven to rotate synchronously by the flywheel body 2. When the permanent magnets (4, 5) are directly opposite the position on the annular rotor 3 without the groove 31, the annular rotor 3 experiences a strong attraction force from the permanent magnets (4, 5). When the permanent magnets (4, 5) are directly opposite the groove 31 on the annular rotor 3, the attraction force is weaker. The spaced structure creates a distinct segmented feel, improving the user experience of this flywheel structure. Furthermore, it eliminates the need for electromagnetic components, effectively avoiding the performance and lifespan limitations caused by electronic components. This flywheel structure is simple in structure, low in production cost, and effectively meets the development needs of modern production. By placing the permanent magnets (4, 5) in a structure that is not in direct contact with the annular rotor 3, the problem of the annular rotor 3 being unable to rotate due to direct attraction of the permanent magnets (4, 5) to the annular rotor 3 is effectively prevented.

[0032] Preferably, the annular rotor 3 is made of silicon steel. While maintaining the hardness of the annular rotor 3, it has high magnetic permeability and low hysteresis characteristics, as well as good resistivity and conductivity. It can effectively reduce hysteresis loss and eddy current loss when magnetic flux passes through it, improve the energy efficiency of the equipment, effectively ensure the magnetic adsorption of the permanent magnets (4, 5) on the annular rotor 3, and ensure the feel of this flywheel structure.

[0033] To ensure the feel of this flywheel component during use, such as Figure 5As shown, the height of the permanent magnets (4, 5) is greater than the outer perimeter of the opening of the groove 31, so that the magnetic attraction of the permanent magnets (4, 5) to the annular rotor 3 is more distinct, effectively ensuring the segmentation of this flywheel structure.

[0034] To further enhance the segmented feel of this flywheel structure, such as Figures 2 to 4 As shown, there are two sets of permanent magnets (4, 5). The two sets of permanent magnets are symmetrically arranged on both sides of the flywheel bracket 1. They are a first permanent magnet 4 arranged on the left side of the flywheel bracket 1 and a second permanent magnet 5 arranged on the right side of the flywheel bracket 1, so that the left and right sides of the annular rotor 3 are subjected to uniform magnetic attraction force, providing the user with a more stable and more obvious segmented feel, thereby improving the user's user experience.

[0035] The distance and specific dimensions between the grooves 31 can be set according to the dimensions of the permanent magnets (4, 5), so as to ensure that when the annular rotor 3 rotates, the first permanent magnet 4 and the second permanent magnet 5 are simultaneously in a position directly facing the groove 31, or the first permanent magnet 4 and the second permanent magnet 5 are not simultaneously in a position directly facing the groove 31, thereby preventing the problem of uneven magnetic attraction on the annular rotor 3 and the lack of obvious segmentation, and effectively ensuring the user experience of this flywheel structure.

[0036] The specific method by which the first permanent magnet 4 and the second permanent magnet 5 are respectively mounted on the flywheel bracket 1 is as follows: Figures 2 to 5 As shown, the flywheel bracket 1 has a first embedding groove 11 for inserting the first permanent magnet 4 and a second embedding groove 12 symmetrical to the first embedding groove 11 for inserting the second permanent magnet 5. The first permanent magnet 4 is inserted into the first embedding groove 11, and the second permanent magnet 5 is inserted into the second embedding groove 12, thereby completing the installation of the first permanent magnet 4 and the second permanent magnet 5 and ensuring the normal operation of this flywheel structure.

[0037] To prevent the first permanent magnet 4 and the second permanent magnet 5 from shifting during use, such as Figures 1 to 5As shown, this flywheel structure also includes a first baffle 6 covering the first embedding groove 11 and limiting the upper end of the first permanent magnet 4, and a second baffle 7 covering the second embedding groove 12 and limiting the upper end of the second permanent magnet 5. By fixing the first baffle 6 to the upper groove of the first embedding groove 11 with screws, the first permanent magnet 4 is fixedly limited to the upper groove of the first embedding groove 11. By fixing the second baffle 7 to the upper groove of the second embedding groove 12 with screws, the second permanent magnet 5 is fixedly limited to the second embedding groove 12. This effectively prevents the first permanent magnet 4 and the second permanent magnet 5 from shifting during use, and effectively ensures the user experience of this flywheel structure.

[0038] Regarding the specific structural design of the first baffle 6, as follows: Figure 2 As shown, the first baffle 6 includes a first upper limit plate 61 that covers the first embedding groove 11 and limits the upper end of the first permanent magnet 4, and a first lower limit plate 62 that is symmetrically arranged on both sides of the lower end face of the first upper limit plate 61.

[0039] Regarding the specific method of installing the first lower limit piece 62, as follows: Figures 2 to 5 As shown, first lower limiting slots 13 are formed on both sides of the first embedding slot 11 for the first lower limiting plate 62 to be inserted. After the first permanent magnet 4 is placed into the first embedding slot 11, the first lower limiting plate 62 is inserted into the first lower limiting slot 13, so that the first upper limiting plate 61 connected to the first lower limiting plate 62 blocks the upper end face of the first permanent magnet 4, thereby preventing the displacement of the first permanent magnet 4 and ensuring the normal operation of this flywheel structure.

[0040] Regarding the specific method of fixing the first lower limit piece 62, as follows: Figures 2 to 5 As shown, a first engaging flange 14 protrudes from the inner wall of the first lower limiting groove 13 near the first embedding groove 11, and a first engaging groove 621 is formed in the middle of the first lower limiting piece 62 for the first engaging flange 14 to engage. When the first lower limiting piece 62 enters the first lower limiting groove 13, the first engaging flange 14 protrudes and engages in the first engaging groove 621, thereby fixing the first lower limiting piece 62 without external force, and thus fixing the position of the first permanent magnet 4, ensuring the normal operation of this flywheel structure.

[0041] Regarding the specific structural design of the second baffle 7, as follows: Figures 2 to 5 As shown, the second baffle 7 includes a second upper limit plate 71 that covers the second embedding groove 12 and limits the upper end of the second permanent magnet 5, and a second lower limit plate 72 that is symmetrically arranged on both sides of the lower end face of the second upper limit plate 71.

[0042] Regarding the specific method of installing the second lower limit piece 72, as follows: Figures 2 to 5 As shown, second lower limiting grooves 15 are formed on both sides of the second embedding groove 12 for the second lower limiting piece 72 to be inserted. After the second permanent magnet 5 is placed into the second embedding groove 12, the second lower limiting piece 72 is inserted into the second lower limiting groove 15, so that the second upper limiting piece 71 connected to the second lower limiting piece 72 blocks the upper end face of the second permanent magnet 5, thereby preventing the displacement of the second permanent magnet 5 and ensuring the normal operation of this flywheel structure.

[0043] Regarding the specific method of fixing the second lower limit piece 72, as follows: Figures 2 to 5 As shown, a second engaging flange 16 protrudes from the inner wall of the second lower limiting groove 15 near the second embedding groove 12, and a second engaging groove 721 is formed in the middle of the second lower limiting piece 72 for the second engaging flange 16 to engage. When the second lower limiting piece 72 enters the second lower limiting groove 15, the second engaging flange 16 protrudes and embeds into the second engaging groove 721, thereby fixing the second lower limiting piece 72 without external force applied, and thus fixing the position of the second permanent magnet 5, ensuring the normal operation of this flywheel structure.

[0044] Preferably, in order to better insert the first lower limiting piece 62 into the first lower limiting groove 13, such as... Figure 2 and Figure 4 As shown, the lower side of the first lower limiting piece 62 is provided with a first inclined guide surface 622 extending from the upper outer side to the lower inner side. When the first lower limiting piece 62 is inserted into the first lower limiting groove 13, the first inclined guide surface 622 first contacts the side wall of the first lower limiting groove 13. Under the inclined guiding action of the first inclined guide surface 622, the first lower limiting piece 62 moves more easily to the middle of the first lower limiting groove 13, thereby making it easier for the first snap-fit ​​flange 14 to snap into the first snap-fit ​​groove 621, improving the efficiency and stability of the installation of the first baffle 6.

[0045] Preferably, in order to better insert the second lower limiting piece 72 into the second lower limiting groove 15, such as... Figure 2 and Figure 4As shown, the lower side of the second lower limiting piece 72 is provided with a second inclined guide surface 722 extending from the upper outer side to the lower inner side. When the second lower limiting piece 72 is inserted into the second lower limiting groove 15, the second inclined guide surface 722 first contacts the side wall of the second lower limiting groove 15. Under the inclined guiding action of the second inclined guide surface 722, the second lower limiting piece 72 moves more easily to the middle of the second lower limiting groove 15, thereby making it easier for the second snap-fit ​​flange 16 to snap into the second lower limiting groove 15, improving the efficiency and stability of the installation of the second baffle 7.

[0046] Preferably, in order to better embed the first snap-fit ​​flange 14 into the first snap-fit ​​groove 621, such as Figure 3 As shown, a third inclined guide surface 141 is formed on the upper end surface of the first snap-fit ​​flange 14, extending obliquely from the upper part of the first embedding groove 11 to the lower part of the first snap-fit ​​groove 621. During the process of the first lower limiting piece 62 being inserted into the first lower limiting groove 13, the lower end surface and side surface of the first lower limiting piece 62 first contact the third inclined guide surface 141. Under the oblique guiding action of the third inclined guide surface 141, the first lower limiting piece 62 is more easily guided to the middle part of the first lower limiting groove 13, making it easier for the first snap-fit ​​flange 14 to snap into the first snap-fit ​​groove 621, thereby improving the efficiency and stability of the installation of the first baffle 6.

[0047] Preferably, in order to better embed the second snap-fit ​​flange 16 into the second snap-fit ​​groove 721, such as Figure 3 As shown, a fourth inclined guide surface 161 is formed on the upper end surface of the second snap-fit ​​flange 16, extending obliquely from the upper part of the second embedding groove 12 toward the lower part of the second snap-fit ​​groove 721. During the process of the second lower limiting piece 72 being inserted into the second lower limiting groove 15, the lower end surface and side surface of the second lower limiting piece 72 first contact the fourth inclined guide surface 161. Under the oblique guiding action of the fourth inclined guide surface 161, the second lower limiting piece 72 is more easily guided to the middle part of the second lower limiting groove 15, making it easier for the second snap-fit ​​flange 16 to snap into the second snap-fit ​​groove 721, thereby improving the efficiency and stability of the installation of the second baffle 7.

[0048] The specific structure of the first upper limit plate 61 and the second upper limit plate 71 can be set according to the actual situation. For example, when set on a mouse, in order to conform to the structure of the human body, it can be set as an overall tilted structure.

[0049] Other operating structures and methods of this flywheel component can be configured according to actual conditions. For example, the flywheel body 2 is provided with a magnetic ring and a Hall element facing the magnetic ring. When the flywheel body 2 rotates, the magnetic ring is driven to rotate synchronously, and the Hall element senses the magnetic ring to output a signal. These are all existing technologies in the art, so they will not be described in detail in this embodiment.

[0050] It should be noted that the flywheel structure with segmented tactile feedback disclosed in this utility model is an improvement on a specific structure, but the specific control method is not an innovation of this utility model. The permanent magnets, magnetic rings, Hall elements, and other components involved in this utility model can be general standard parts or components known to those skilled in the art. Their structures, principles, and control methods are all known to those skilled in the art through technical manuals or conventional experimental methods.

[0051] The above description is merely a preferred embodiment of the present utility model and does not constitute any limitation on the technical scope of the present utility model. Therefore, other structures obtained by using the same or similar technical features as the above embodiments of the present utility model are all within the protection scope of the present utility model.

Claims

1. A flywheel structure with a segmented tactile feel, comprising a bracket and a flywheel body rotatably mounted on the bracket, characterized in that: It also includes an annular rotor disposed on the flywheel body. The annular rotor is made of magnetic material. The outer ring wall of the annular rotor is provided with grooves at intervals. At least one permanent magnet is disposed on the support, which is opposite to and non-contact with the grooves of the annular rotor. The permanent magnet performs magnetic interference on the annular rotor.

2. The flywheel structural component with segmented tactile feedback according to claim 1, characterized in that: The height of the permanent magnet is greater than the outer perimeter of the groove opening.

3. The flywheel structural component with segmented tactile feedback according to claim 1, characterized in that: The number of permanent magnets is two sets, and the two sets of permanent magnets are symmetrically arranged on both sides of the flywheel bracket. They are a first permanent magnet arranged on the left side of the flywheel bracket and a second permanent magnet arranged on the right side of the flywheel bracket.

4. The flywheel structure with segmented tactile feedback according to claim 3, characterized in that: The flywheel bracket has a first embedding groove for inserting the first permanent magnet and a second embedding groove symmetrical to the first embedding groove for inserting the second permanent magnet.

5. The flywheel structure with segmented tactile feedback according to claim 4, characterized in that: It also includes a first baffle plate that covers the first embedding groove and limits the upper end of the first permanent magnet, and a second baffle plate that covers the second embedding groove and limits the upper end of the second permanent magnet.

6. The flywheel structural component with segmented tactile feedback according to claim 5, characterized in that: The first baffle includes a first upper limit plate that covers the first embedding groove and limits the upper end of the first permanent magnet, and a first lower limit plate that is symmetrically disposed on both sides of the lower end face of the first upper limit plate; the second baffle includes a second upper limit plate that covers the second embedding groove and limits the upper end of the second permanent magnet, and a second lower limit plate that is symmetrically disposed on both sides of the lower end face of the second upper limit plate.

7. The flywheel structural component with segmented tactile feedback according to claim 6, characterized in that: The first embedding groove has first lower limiting grooves formed on both sides for the insertion of the first lower limiting piece. A first engaging flange protrudes from the inner wall of the first lower limiting groove near the first embedding groove. A first engaging groove is formed in the middle of the first lower limiting piece for the first engaging flange to engage. The second embedding groove has second lower limiting grooves formed on both sides for the insertion of the second lower limiting piece. A second engaging flange protrudes from the inner wall of the second lower limiting groove near the second embedding groove. A second engaging groove is formed in the middle of the second lower limiting piece for the second engaging flange to engage.

8. The flywheel structural component with segmented tactile feedback according to claim 6, characterized in that: The lower side of the first lower limit piece is provided with a first inclined guide surface extending from the upper outer direction to the lower inner direction; the lower side of the second lower limit piece is provided with a second inclined guide surface extending from the upper outer direction to the lower inner direction.

9. The flywheel structure with segmented tactile feedback according to claim 7, characterized in that: A third inclined guide surface is formed on the upper end surface of the first snap-fit ​​flange, extending inclinedly from the upper part of the first insert groove toward the lower part of the first snap-fit ​​groove; a fourth inclined guide surface is formed on the upper end surface of the second snap-fit ​​flange, extending inclinedly from the upper part of the second insert groove toward the lower part of the second snap-fit ​​groove.