A smart watch quick release watch face assembly

The quick-release mechanism design enables rapid disassembly and installation of the smartwatch face, solving the problems of cumbersome disassembly and easy loss of pins in existing technologies, and improving operational convenience and stability.

CN224501164UActive Publication Date: 2026-07-14深圳市海睿创科技有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
深圳市海睿创科技有限公司
Filing Date
2025-10-09
Publication Date
2026-07-14

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  • Figure CN224501164U_ABST
    Figure CN224501164U_ABST
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Abstract

The utility model discloses a kind of smart watch quick-release type dial assembly, including smart watch body and quick-release mechanism;The smart watch body includes watch case, watchband and dial body;Two the watchband is symmetrically arranged on the both sides of watch case by screw, and two the watchband is connected by needle buckle mechanism between;The dial body is connected with watch case by quick-release mechanism;The quick-release mechanism includes plug-in assembly;The plug-in assembly includes plug-in slot, plug-in block, limiting slot and limiting block;Plug-in slot is set on the watch case;The plug-in block is inserted in plug-in slot and is fixedly connected with dial body;At least one limiting slot is set on the plug-in block;The limiting block is slidably arranged in limiting slot and is fixedly connected with plug-in slot, this smart watch quick-release type dial assembly, simple and reasonable structure, ingenious design, not only convenient and fast to dial body disassembly, but also, dial body position stability can be improved, use effect is better.
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Description

Technical Field

[0001] This utility model relates to the field of smartwatch technology, specifically to a quick-release dial assembly for a smartwatch. Background Technology

[0002] A smartwatch is a watch with information processing capabilities that meets the basic technical requirements of a watch. In addition to telling time, a smartwatch should also have one or more functions such as reminders, navigation, calibration, monitoring, and interaction; the display methods include pointers, numbers, images, etc.

[0003] For example, Chinese utility model patent CN223193282U discloses a quick-release watch face assembly for a smartwatch, comprising: a smartwatch body with strap mounting positions on both sides and a motherboard on top; a watch face assembly with a protective glass and a display panel below it, the display panel corresponding to the motherboard; and a quick-release connection structure between the smartwatch body and the watch face assembly, enabling installation of both components. This utility model uses a quick-release connection structure, facilitating rapid installation and removal between the smartwatch body and the watch face assembly, improving the convenience of replacement and maintenance. A positioning structure and a magnetic fixing structure ensure a stable connection between the watch face assembly and the smartwatch body, guaranteeing safety and stability during wear.

[0004] Currently, smartwatches on the market are prone to damage during prolonged use, requiring replacement or repair. However, disassembling a smartwatch face often requires a pin. This pin is inserted into a pin hole to push a guide block back into the guide slot, making it easier to remove the face. This process is not only cumbersome, but the small pin is also easily lost, affecting the usability of the smartwatch face. Utility Model Content

[0005] The purpose of this invention is to provide a quick-release watch face assembly for smartwatches, in order to solve the problem of the cumbersome disassembly of the watch face mentioned in the background art.

[0006] To achieve the above objectives, this utility model provides the following technical solution: a quick-release dial assembly for a smartwatch, comprising a smartwatch body and a quick-release mechanism; the smartwatch body includes a case, a strap, and a dial body; two straps are symmetrically disposed on both sides of the case by screws, and the two straps are connected by a buckle mechanism; the dial body is connected to the case via the quick-release mechanism; the quick-release mechanism includes a plug-in assembly; the plug-in assembly includes a plug-in slot, a plug-in block, a limiting slot, and a limiting block; the case has a plug-in slot; the plug-in block is inserted into the plug-in slot and fixedly connected to the dial body; the plug-in block has at least one limiting slot; the limiting block slides through the limiting slot and is fixedly connected to the plug-in slot.

[0007] Preferably, the quick-release mechanism further includes a locking assembly; the locking assembly includes a receiving groove, a moving groove, a hollow groove, a locking groove, a rotating rod, a gear, a rack, and a locking block; the limiting block has a receiving groove; two moving grooves are symmetrically formed in the center of the receiving groove; two hollow grooves are symmetrically formed on both sides of the limiting block, and the hollow grooves are connected to the moving grooves; two locking grooves are symmetrically formed on both sides of the inner wall of the limiting groove; one end of the rotating rod is rotatably connected to the receiving groove via a rotating shaft, and the other end extends to the outside through the receiving groove; the gear is sleeved on the rotating rod; the rack slides through the moving groove, and the gear meshes with the rack and rotates; the locking block slides through the hollow groove and is fixedly connected to the end of the rack, and the locking block is inserted into the locking groove.

[0008] Preferably, the locking block has an isosceles triangular structure, and the inclined surface of the locking block is arranged in the horizontal direction.

[0009] Preferably, the locking assembly further includes a movable groove, a movable block, and a spring A; the movable groove is provided in the movable groove; the movable block slides through the movable groove via a slowing assembly and is fixedly connected to the rack; the two ends of the spring A are fixedly connected to the inner wall of the movable groove and the movable block, respectively.

[0010] Preferably, the damping component includes a sliding groove, a damping block, a damping groove, and a spring B; at least one sliding groove is provided on the movable block; the damping block slides through the sliding groove; at least one damping groove is provided in the movable groove; and both ends of the spring B are fixedly connected to the inner wall of the sliding groove and the damping block, respectively.

[0011] Preferably, the damping block has a right-angled trapezoidal structure, and the dimension of the damping block on the side closer to spring B is larger than the dimension of the damping block on the side farther from spring B.

[0012] Preferably, the damping groove has a right-angled triangular structure, and the inclined surface of the damping groove is in contact with the inclined surface of the damping block.

[0013] Preferably, the elastic strength of spring B is less than that of spring A.

[0014] Compared with the prior art, the beneficial effects of this utility model are:

[0015] 1. This utility model features a quick-release mechanism. By rotating the anti-slip button on the rotating rod, the rotating rod rotates through the shaft and into the receiving groove, causing the gear to rotate. This gear meshes with the rack, causing the rack to slide in the moving groove. The two racks move relative to each other, causing the locking block to slide in the empty groove and the locking groove, and the movable block to slide in the movable groove. This causes spring A to contract until the side of the rack contacts the inner wall of the receiving groove. At this point, the locking block moves out of the locking groove. Then, the dial body is moved upward, causing the insertion block to slide upward in the insertion groove, and the limiting block to slide in the limiting groove, until the insertion block moves out of the insertion groove. This completes the disassembly of the dial body. Compared with the prior art, this utility model has a simple and reasonable structure and ingenious design. It not only facilitates and quickly disassembles the dial body but also improves the stability of the dial body's position, resulting in better performance.

[0016] 2. By setting up a slowing component, when the two racks move in opposite directions, the movable block will slide in the movable groove. Since the elastic strength of spring B is less than that of spring A, the inclined surface of the slowing block will press against the inclined surface of the slowing groove, causing the slowing block to slide in the opposite direction in the slowing groove. This causes spring B to contract under force, and the force generated by the contraction of spring B can cancel out the force generated by the extension of spring A, thereby slowing down the movement speed of the movable block. Furthermore, by having the inclined surface of the slowing groove in contact with the inclined surface of the slowing block, the slowing block and the slowing groove can disperse the force generated by the extension of spring A, thereby achieving a force relief effect. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0018] Figure 2 This is a cross-sectional view of the overall structure of this utility model;

[0019] Figure 3 This is a partial structural schematic diagram of the present invention;

[0020] Figure 4 This is a partial structural breakdown diagram of the present invention;

[0021] Figure 5 This is a partially disassembled sectional view of the present invention.

[0022] Figure 6 For the present utility model Figure 2 Enlarged view of point A in the middle;

[0023] Figure 7 For the present utility model Figure 6Enlarged diagram of point B in the middle.

[0024] In the picture:

[0025] 1. Smartwatch body; 2. Quick-release mechanism; 3. Connecting component; 4. Locking component; 5. Relief component; 101. Watch case; 102. Watch strap; 103. Watch face body; 301. Connecting slot; 302. Connecting block; 303. Limiting slot; 304. Limiting block; 401. Receiving slot; 402. Moving slot; 403. Empty slot; 404. Locking slot; 405. Rotating rod; 406. Gear; 407. Rack; 408. Locking block; 409. Moving slot; 410. Moving block; 411. Spring A; 501. Sliding slot; 502. Relief block; 503. Relief slot; 504. Spring B. Detailed Implementation

[0026] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments 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 of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0027] Please see Figures 1 to 7 This utility model provides a technical solution: a quick-release dial assembly for a smartwatch, including a smartwatch body 1 and a quick-release mechanism 2; the smartwatch body 1 includes a watch case 101, a watch strap 102 and a dial body 103; two watch straps 102 are symmetrically arranged on both sides of the watch case 101 by screws, and the two watch straps 102 are connected by a buckle mechanism; the dial body 103 is connected to the watch case 101 by the quick-release mechanism 2;

[0028] The quick-release mechanism 2 includes a plug-in assembly 3; the plug-in assembly 3 includes a plug-in slot 301, a plug-in block 302, a limiting slot 303, and a limiting block 304; the watch case 101 has a plug-in slot 301; the plug-in block 302 is inserted into the plug-in slot 301 and fixedly connected to the watch face body 103; the plug-in block 302 has a limiting slot 303; the limiting block 304 slides through the limiting slot 303 and is fixedly connected to the plug-in slot 301;

[0029] The quick-release mechanism 2 also includes a locking assembly 4; the locking assembly 4 includes a receiving groove 401, a moving groove 402, a hollow groove 403, a locking groove 404, a rotating rod 405, a gear 406, a rack 407, a locking block 408, a movable groove 409, a movable block 410, and a spring A411; the limiting block 304 has a receiving groove 401; two moving grooves 402 are symmetrically opened in the center of the receiving groove 401; two hollow grooves 403 are symmetrically opened on both sides of the limiting block 304, and the hollow grooves 403 are connected to the moving grooves 402; two locking grooves 404 are symmetrically opened on both sides of the inner wall of the limiting groove 303; one end of the rotating rod 405 is rotatably connected to the receiving groove 401 through a rotating shaft, and the other end extends to the outside through the receiving groove 401; the gear 406 is fixedly connected to the rotating rod 405; the rack 407 slides... The gear 406 is installed in the moving groove 402 and meshes with the rack 407 to rotate; the locking block 408 is slidably installed in the empty groove 403 and fixedly connected to the end of the rack 407, and the locking block 408 is inserted into the locking groove 404; the locking block 408 has an isosceles triangular structure and the inclined surface of the locking block 408 is set in the horizontal direction, which can not only guide the insertion of the locking block 408 and the locking groove 404 through the inclined surface of the locking block 408, but also improve the stability of the position of the dial body 103 through the plane of the locking block 408; the moving groove 402 has a movable groove 409; the movable block 410 is slidably installed in the movable groove 409 through the slowing component 5 and fixedly connected to the rack 407; the two ends of the spring A411 are fixedly connected to the inner wall of the movable groove 409 and the movable block 410, respectively.

[0030] This utility model, by setting up a quick-release mechanism 2, causes the rotating rod 405 to rotate via a shaft and the receiving groove 401 by rotating the anti-slip button on the rotating rod 405. This causes the gear 406 to rotate, meshing with the rack 407 and causing the rack 407 to slide in the moving groove 402. This movement of the two racks 407 relative to each other causes the locking block 408 to slide in the empty groove 403 and the locking groove 404, and the movable block 410 to slide in the movable groove 409. This causes the spring A411 to contract under force until the side of the rack 407 contacts the receiving groove 401. When the side wall contacts the lock, the locking block 408 moves out of the locking groove 404. Then, the dial body 103 is moved upward, causing the insertion block 302 to slide upward in the insertion groove 301, and the limiting block 304 to slide in the limiting groove 303, until the insertion block 302 moves out of the insertion groove 301, thus completing the disassembly of the dial body 103. Compared with the prior art, this utility model has a simple and reasonable structure and ingenious design. It not only facilitates and quickly disassembles the dial body 103, but also improves the stability of the position of the dial body 103, resulting in better performance.

[0031] In a preferred embodiment, the mitigation component 5 includes a sliding groove 501, a mitigation block 502, a mitigation groove 503, and a spring B504; the sliding groove 501 is provided on the movable block 410; the mitigation block 502 slides through the sliding groove 501; the mitigation groove 503 is provided in the movable groove 409; the two ends of the spring B504 are fixedly connected to the inner wall of the sliding groove 501 and the mitigation block 502, respectively; the mitigation block 502 has a right-angled trapezoidal structure, and the dimension of the mitigation block 502 on the side closer to the spring B504 is larger than the dimension of the mitigation block 502 on the side farther from the spring B504; the mitigation groove 503 has a right-angled triangular structure, and the inclined surface of the mitigation groove 503 contacts the inclined surface of the mitigation block 502; the elastic strength of the spring B504 is less than the elastic strength of the spring A411; when the side of the rack 407 contacts the inner wall of the receiving groove 401, the spring A411 can continue to contract, and the mitigation block 502 still contacts the inner wall of the mitigation groove 503.

[0032] This invention, by setting a slowing component 5, causes the movable block 410 to slide within the movable groove 409 when the two racks 407 move in opposite directions. Since the elastic strength of spring B504 is less than that of spring A411, the inclined surface of the slowing block 502 presses against the inclined surface of the slowing groove 503, causing the slowing block 502 to slide in the opposite direction within the slowing groove 503. This causes spring B504 to contract under force, and the force generated by the contraction of spring B504 can cancel out the force generated by the extension of spring A411, thereby slowing down the movement speed of the movable block 410. Furthermore, the contact between the inclined surface of the slowing groove 503 and the inclined surface of the slowing block 502 allows the slowing block 502 and the slowing groove 503 to disperse the force generated by the extension of spring A411, thus achieving a force relief effect.

[0033] The smartwatch body 1 is a conventional instrument. Its working principle, size and model are not related to the problem solved by this application, so they will not be described in detail. The control method of this utility model is through a controller. The control circuit of the controller can be implemented by a person skilled in the art through simple programming. The power supply is also common knowledge in the art. Furthermore, this utility model is mainly used to protect mechanical devices, so the control method and circuit connection will not be explained in detail.

[0034] Working principle: During disassembly, firstly, by rotating the anti-slip button on the rotating rod 405, the rotating rod 405 rotates through the shaft and into the receiving groove 401, causing the gear 406 to rotate. This causes the gear 406 to mesh with the rack 407, causing the rack 407 to slide within the moving groove 402. This movement of the two racks 407 relative to each other causes the locking block 408 to slide within the empty groove 403 and the locking groove 404, and the movable block 410 to slide within the movable groove 409. This causes the spring A411 to contract under force, and at this time, the spring B504 no longer... Under force, it begins to stretch, causing the deceleration block 502 to slide within the deceleration groove 503, ensuring that the inclined surface of the deceleration groove 503 remains in contact with the inclined surface of the deceleration block 502 until the side of the rack 407 contacts the inner wall of the receiving groove 401. At this point, the locking block 408 moves out of the locking groove 404. Then, the dial body 103 is moved upward, causing the insertion block 302 to slide upward within the insertion groove 301, and the limiting block 304 to slide within the limiting groove 303, until the insertion block 302 moves out of the insertion groove 301, thus completing the disassembly of the dial body 103.

[0035] During installation, insert the plug block 302 into the plug slot 301 and slide it downwards within the slot 301, causing the limiting block 304 to slide in the opposite direction within the limiting groove 303, until the bottom surface of the plug block 302 contacts the bottom wall of the plug slot 301. At this point, release the anti-slip button on the rotating rod 405. Under the elastic force of the spring A411, the movable block 410 will slide in the opposite direction within the movable groove 409, causing the rack 407 to slide in the opposite direction within the moving groove 402. This causes the gear 406 to mesh and rotate with the rack 407, allowing the gear 406 to drive the rotating rod 405 to rotate through the shaft and into the receiving groove 401. The reverse rotation causes the two racks 407 to move away from each other, causing the locking block 408 to slide in the opposite direction within the slot 403. Since the elastic strength of spring B504 is less than that of spring A411, the inclined surface of the deceleration block 502 will press against the inclined surface of the deceleration groove 503, causing the deceleration block 502 to slide in the opposite direction within the deceleration groove 503. This causes spring B504 to contract under force, and the force generated by the contraction of spring B504 can cancel out the force generated by the extension of spring A411, thereby slowing down the movement speed of the movable block 410 until the locking block 408 is inserted into the locking groove 404.

[0036] The above is the entire working process of the device, and all contents not described in detail in this specification are existing technologies known to those skilled in the art.

[0037] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A quick-release watch face assembly for a smartwatch, characterized in that, The watch includes a smartwatch body (1) and a quick-release mechanism (2); the smartwatch body (1) includes a watch case (101), a watch strap (102), and a watch face (103); two watch straps (102) are symmetrically arranged on both sides of the watch case (101) by screws, and the two watch straps (102) are connected to each other by a buckle mechanism; the watch face (103) is connected to the watch case (101) by the quick-release mechanism (2); the quick-release mechanism (2) includes a plug-in component (3); the plug-in component (3) Includes a plug groove (301), a plug block (302), a limiting groove (303), and a limiting block (304); the watch case (101) has a plug groove (301); the plug block (302) is inserted into the plug groove (301) and fixedly connected to the dial body (103); the plug block (302) has at least one limiting groove (303); the limiting block (304) slides through the limiting groove (303) and is fixedly connected to the plug groove (301).

2. The quick-release dial assembly for a smartwatch according to claim 1, characterized in that, The quick-release mechanism (2) further includes a locking assembly (4); the locking assembly (4) includes a receiving groove (401), a moving groove (402), a hollow groove (403), a locking groove (404), a rotating rod (405), a gear (406), a rack (407), and a locking block (408); the limiting block (304) has a receiving groove (401); two moving grooves (402) are symmetrically opened in the center of the receiving groove (401); two hollow grooves (403) are symmetrically opened on both sides of the limiting block (304), and the hollow grooves (403) are connected to the moving grooves (402); the limiting groove (303) Two locking grooves (404) are symmetrically opened on both sides of the inner wall; one end of the rotating rod (405) is rotatably connected to the receiving groove (401) through a rotating shaft, and the other end extends to the outside through the receiving groove (401); the gear (406) is sleeved on the rotating rod (405); the rack (407) is slidably inserted in the moving groove (402), and the gear (406) meshes and rotates with the rack (407); the locking block (408) is slidably inserted in the empty groove (403) and fixedly connected to the end of the rack (407), and the locking block (408) is inserted into the locking groove (404).

3. The quick-release dial assembly for a smartwatch according to claim 2, characterized in that, The locking block (408) has an isosceles triangular structure, and the inclined surface of the locking block (408) is set in the horizontal direction.

4. The quick-release dial assembly for a smartwatch according to claim 2, characterized in that, The locking assembly (4) further includes a movable groove (409), a movable block (410), and a spring A (411); the movable groove (409) is provided in the movable groove (402); the movable block (410) slides through the movable groove (409) through the deceleration assembly (5) and is fixedly connected to the rack (407); the two ends of the spring A (411) are fixedly connected to the inner wall of the movable groove (409) and the movable block (410) respectively.

5. A quick-release dial assembly for a smartwatch according to claim 4, characterized in that, The deceleration component (5) includes a sliding groove (501), a deceleration block (502), a deceleration groove (503), and a spring B (504); at least one sliding groove (501) is provided on the movable block (410); the deceleration block (502) slides through the sliding groove (501); at least one deceleration groove (503) is provided in the movable groove (409); and the two ends of the spring B (504) are fixedly connected to the inner wall of the sliding groove (501) and the deceleration block (502) respectively.

6. A quick-release dial assembly for a smartwatch according to claim 5, characterized in that, The deceleration block (502) has a right-angled trapezoidal structure, and the size of the deceleration block (502) on the side closer to the spring B (504) is larger than the size of the deceleration block (502) on the side farther away from the spring B (504).

7. A quick-release dial assembly for a smartwatch according to claim 6, characterized in that, The damping groove (503) has a right-angled triangular structure, and the inclined surface of the damping groove (503) is in contact with the inclined surface of the damping block (502).

8. A quick-release dial assembly for a smartwatch according to claim 6, characterized in that, The elastic strength of spring B (504) is less than that of spring A (411).