Quick-release lock mechanism with magnetic positioning function
The quick-release locking mechanism with magnetic positioning and mechanical locking addresses the inconvenience and instability of conventional methods by enabling single-handed operation and enhanced stability in vibrating environments.
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Utility models
- Current Assignee / Owner
- 范裕雄
- Filing Date
- 2026-04-03
- Publication Date
- 2026-06-08
AI Technical Summary
Conventional lock mechanisms for attaching electronic devices to bicycles or motorcycles require multiple operation steps, are inconvenient for quick attachment and detachment, and lack stability in vibrating environments, especially when using magnet adsorption-type structures.
A quick-release locking mechanism combining mechanical locking with magnetic attraction, featuring a first and second joining member with magnetic adsorption elements and extendable locking members, allowing single-handed operation and enhanced stability through a double seismic isolation system.
Enables quick, single-handed attachment and detachment with high-strength locking, maintaining stability during vibrations, and allowing angle adjustment of the electronic device, while extending its service life.
Smart Images

Figure 0003256140000001_ABST
Abstract
Description
Technical Field
[0001] The present invention relates to the technical field of a lock system attached to a handheld electronic device, and particularly to a quick release lock mechanism having a magnetic positioning function.
Background Art
[0002] Portable electronic devices (such as smartphones, navigation devices or sports recording devices) are widely used in outdoor activities and mobile environments. During cycling or motorcycling, users often fix these electronic devices to the positions of handlebars, support rods, or other brackets to facilitate displaying or operating information in real time.
[0003] Conventional structures for fixing electronic devices include clamp-type, mechanical engagement-type, and magnet adsorption-type designs. Clamp-type or mechanical engagement-type structures can provide a certain fixing force, but in the process of their attachment and detachment, multiple operation steps are often required, usually requiring two-handed operation, which is inconvenient in the usage environment of motorcycles or bicycles where the electronic device needs to be quickly attached and detached.
[0004] Magnet adsorption-type fixing structures usually have the advantage of being easy to operate, but their fixing force may be limited by the magnitude of the magnetic force and is usually only suitable for use in a stationary state. When attached to a motorcycle or bicycle, due to vibrations caused by driving on uneven roads, the electronic device may sway, tilt, and even fall off.
[0005] In some prior arts, attempts have been made to combine a magnet adsorption structure and a mechanical fixing structure, but the overall structure may become complex, or the operation method is not sufficiently convenient, so an ideal balance has not been achieved between the convenience of operation and the stability of fixing. Therefore, the inventor of the present invention conceived an improved structure that combines quick attachment and detachment, single-handed operation, and stable fixation of an electronic device in a vibrating environment. [Overview of the project] [Problems that the invention aims to solve]
[0006] The main objective of this invention is to provide a quick-release locking mechanism with magnetic positioning functionality, achieving high-strength locking through a design that primarily uses mechanical locking and secondary magnetic attraction, while also offering the convenience of quick attachment and detachment with one hand. [Means for solving the problem]
[0007] To achieve the aforementioned objective, this invention employs the following technical means.
[0008] The present invention relates to a quick-release locking mechanism having a magnetic positioning function, comprising a first joining member and a second joining member, the first joining member having a surrounding wall which surrounds a hollow mounting groove chamber in an annular shape and is provided with at least one first magnetic adsorption element, the second joining member comprising a support seat and an operating member, the center of the support seat forming a convex abutment portion, a plurality of extendable or retractable locking members provided around the abutment portion, and the support seat in the outer peripheral region of the abutment portion At least one second magnetic adsorption element is provided, the position of which corresponds to the first magnetic adsorption element, the operating member is installed on the support seat, the operating member can be linked with a transmission structure inside the support seat, and by pressing the operating member, the locking member can be retracted into the abutment portion, and when the abutment portion is inserted into the mounting groove chamber, the multiple locking members are locked to the inner edge of the enclosure wall, and an auxiliary fixing force is generated by the mutual attraction between the second magnetic adsorption element and the first magnetic adsorption element.
[0009] In one preferred implementation, the abutment is a cylindrical housing formed in the central region of the support seat and projecting outward, wherein the diameter of the abutment is smaller than the diameter of the opening in the enclosure.
[0010] In one preferred implementation, the circumferential outer wall of the abutment has a plurality of windows, each locking member is restricted in the corresponding window and is movable or extendable radially, the locking member has an outward-facing side wall, the top of which has an outward-projecting slanted hook block, and when the plurality of locking members are locked, the diameter formed by two symmetrically positioned side walls is greater than the diameter of the outer wall of the abutment.
[0011] In one preferred implementation, the operating member is interlocked with the locking member via a transmission structure inside the support seat, and a bottom casing is further provided at the bottom of the support seat, forming a housing space between the support seat and the bottom casing, which houses a plurality of the locking members, interlocking members and some of the structures of the operating member.
[0012] In one preferred implementation, the interlocking member within the support seat is movable only in the axial direction, the interlocking member is provided with a plurality of inclined guide grooves, each locking member is provided with an inclined guide member and is inserted into the corresponding inclined guide groove, the operating member is pivotally attached to the bottom casing and has a lift block that contacts the interlocking member, the operating member drives the interlocking member to move in the axial direction, the interlocking member moves the locking member radially.
[0013] In one preferred implementation, a plurality of first springs are provided inside the abutting portion, each of which contacts the corresponding locking member, and the first springs provide an elastic force that causes the locking member to extend outward.
[0014] In one preferred embodiment, at least one second spring is provided within the support seat, the second spring is in contact with the interlocking member, and the second spring provides an elastic force that returns the interlocking member to its original position.
[0015] In one preferred embodiment, the support seat is attached to the base in a manner that allows it to be elastically raised and lowered, and at least one elastic member is provided between the support seat and the base, and the support seat is capable of cushioning displacement relative to the base.
[0016] In one preferred implementation, the support seat has a plurality of stopper columns extending downward, and compression springs, which are elastic members, are fitted around the outer circumference of the stopper columns; the base seat is provided with a plurality of fitting holes through which the stopper columns pass; and a plurality of mounting screws are screwed onto the stopper columns, thereby limiting the furthest distance between the support seat and the base seat, and compressing the elastic members between them.
[0017] In one preferred implementation, an auxiliary seismic isolation structure is further provided below the base, and the auxiliary seismic isolation structure includes a support member, a connecting member, and a plurality of buffer members sandwiched between the two, and the auxiliary seismic isolation structure together with the elastic member constitutes a double seismic isolation mechanism.
[0018] As one preferred implementation, the auxiliary seismic isolation structure includes a support member, a plurality of buffer members, a connecting member, and a plurality of locking screws, wherein the plurality of buffer members are installed between the support member and the connecting member, the locking screws pass sequentially through the connecting member, the buffer members, and the support member and are locked to the bottom surface of the base, and the pre-compression ratio of the buffer members can be controlled by adjusting the degree of tightening of the locking screws, thereby further adjusting the seismic isolation damping effect. [Effects of the Invention]
[0019] Compared with the prior art, the present invention provides a quick-release lock mechanism with a magnetic positioning function. When the first joining member and the second joining member approach each other, they can be automatically guided and aligned by the magnetic attraction force generated by the second magnetic adsorption element and the first magnetic adsorption element. In addition, by combining with the mechanical locking relationship between the locking member and the surrounding wall, a high-strength anti-drop lock is provided. Also, after the two are fixed, they can rotate relative to each other, and the viewing angle of the electronic device can be adjusted by rotating relatively, improving the convenience in use. Moreover, it has a structure of a multiple buffer mechanism, and a double seismic isolation system can be constituted by an auxiliary seismic isolation structure composed of an elastic member and a buffer member between the support base and the base, effectively absorbing the impact and vibration generated when the carrier travels on uneven ground, and further extending the service life of the electronic device. Additionally, the design allows for single-handed operation during use, simplifying the unlocking process. When the user removes the device, the locking state of the machine can be released by simply pressing with one hand, greatly improving the convenience and safety of outdoor use.
Brief Description of the Drawings
[0020] [Figure 1] It is a perspective view of the present invention. [Figure 2] It is a cross-sectional view of the AA plane in FIG. 1. [Figure 3] It is an exploded view of the second joining member of the present invention. [Figure 4] It is an exploded view of some members of the present invention from another angle. [Figure 5] It is a cross-sectional view in which the locking member of the present invention retreats to the butting portion. [Figure 6] It is a cross-sectional view of the BB plane in FIG. 2. [Figure 7] It is a perspective view of the auxiliary seismic isolation structure of the present invention. [Figure 8] It is an exploded view of the auxiliary seismic isolation structure of the present invention. [Figure 9] It is a cross-sectional view of the auxiliary seismic isolation structure of the present invention. [Figure 10] It is a perspective view of the actual use state of the present invention.
Best Mode for Carrying Out the Invention
[0021] Hereinafter, the technical means of the present invention will be clearly and completely described in connection with specific embodiments and the accompanying drawings. When an element is referred to as being "attached or fixed to" another element, it means that it may be directly attached to the other element, or there may be an element disposed in the center. When an element is regarded as being "connected to" another element, it means that it may be directly connected to the other element, or there may be an element disposed in the center at the same time.
[0022] In the illustrated embodiment, the indications of directions such as up, down, left, right, front, and back are relative, and are used to explain that the structures and movements of different components in the present invention are relative. When the components are in the positions shown in the figure, these indications are appropriate. However, when the description of the position of the element changes, these indications also change accordingly.
[0023] Unless otherwise defined, all technical and scientific terms used in this specification have the same meaning as commonly understood by one of ordinary skill in the art. The terms used in this specification are for the purpose of describing specific embodiments only and are not intended to limit the present invention. The term "and / or" used in this specification includes any and all combinations of one or more of the listed related items.
[0024] As shown in FIG. 1, it is a perspective view of the present invention. The present invention is a quick release lock mechanism having a magnetic positioning function, and includes a first joining member 10 and a second joining member 20. The first joining member 10 is used to be fixed to an electronic device or a housing for accommodating the electronic device.
[0025] The second connecting member 20 can be used as part of a bracket that supports electronic equipment, and the bracket can be detachably attached to the support frame of a bicycle or motorcycle and used to stably support the electronic equipment in an outdoor environment. The structural design of this invention allows the user to quickly engage or unlock the first connecting member 10 and the second connecting member 20 by operating them with one hand, thereby improving convenience of use and operational efficiency.
[0026] The first joining member 10 has an enclosure wall 11, and the internal region surrounded by the enclosure wall 11 forms a mounting groove chamber 13, and the first joining member 10 is provided with at least one first magnetic adsorption element 12. The second joining member 20 includes a support seat 21 and an operating member 22, the support seat 21 having a convex abutment portion 23 in its center, and the outer wall surrounding the abutment portion 23 having a plurality of locking members 24 that can extend or retract relative to the abutment portion 23, the support seat 21 having at least one second magnetic adsorption element 25 fitted to the surface of the outer peripheral region of the abutment portion 23, the position of the second magnetic adsorption element 25 corresponding to the first magnetic adsorption element 12, the operating member 22 being rotatably mounted outside the support seat 21 and being able to interlock with the locking member 24 via a transmission structure inside the support seat 21, and pressing the operating member 22 can retract the locking member 24 into the abutment portion 23.
[0027] As a result, when the user inserts the abutting portion 23 of the second joining member 20 into the mounting groove chamber 13 of the first joining member 10, the locking member 24 retracts first and then extends to lock onto the inner edge of the enclosure wall 11, mechanically locking the second joining member 20 and the first joining member 10. At the same time, the second magnetic adsorption element 25 magnetically attracts the first magnetic adsorption element 12 and provides auxiliary fixing force, thereby reliably maintaining the locked state of both the first joining member 10 and the second joining member 20.
[0028] When a user attempts to remove an electronic device, simply by pressing the operating member 22 with one hand, the locking member 24 retracts via the internal transmission structure, releasing the locking member 24 from the enclosure 11, and the second connecting member 20 quickly detaches from the first connecting member 10. The design of this invention allows for quick locking when the user intends to use the device and can be operated with one hand when attempting to release the lock, achieving the necessary convenience and operational efficiency.
[0029] Furthermore, in the locked state, after applying force, the first joint member 10 and the second joint member 20 remain rotatable relative to each other, allowing for easy adjustment of the viewing angle of the electronic device. After the external force is removed, the first magnetic adsorption element 12 and the second magnetic adsorption element 25 attract each other, generating a fixing force that prevents the vehicle from shifting while in motion.
[0030] Next, we will explain the structure of each component in more detail.
[0031] Referring also to Figure 2, the main body of the first joining member 10 is an annular disc shape, the surrounding wall 11 is annular and surrounds the annular region of the first joining member 10, forming the mounting groove chamber 13. The mounting groove chamber 13 is provided in conjunction with the surrounding wall 11 for the locking member 24 to be locked therein.
[0032] The outward-facing surface of the enclosure 11 is a conical slope 111 into which the locking member 24 enters. The first magnetic adsorption element 12 is fitted onto the outer surface of the first joining member 10. In this embodiment, the first magnetic adsorption element 12 is annular and made of a metal or a material that can be attracted to a magnet.
[0033] In this embodiment, the first joining member 10 has an adhesive 14 on the side opposite to the enclosure wall 11, and the adhesive 14 is used to attach it to the back of the electronic device. The electronic device is, for example, a mobile phone, but is not limited to this, and the first joining member 10 may also be part of a protective case that houses the electronic device. In the embodiment where it is a protective case, the first joining member 10 is a structure in which the housing protrudes outward.
[0034] Referring also to Figure 3, the second joining member 20 includes the support seat 21 and the operating member 22, the support seat 21 having a plurality of locking members 24 movably provided therein, and when the user presses the operating member 22, the locking members 24 retract into the abutting portion 23 via a transmission structure located inside the support seat 21.
[0035] The second magnetic adsorption element 25 is fitted onto the surface of the outer peripheral region of the abutting portion 23 on the support seat 21, and there is at least one of them. In this embodiment, multiple arc-shaped second magnetic adsorption elements 25 surround each other to form an annular body, and in this embodiment, the second magnetic adsorption element 25 is a magnet. The surface of the support seat 21 is further provided with a cushion 26 to cover the second magnetic adsorption element 25, and the cushion 26 can be made of silicone rubber, soft fabric, or other elastic material. The cushion 26 does not affect the magnetic adsorption of the second magnetic adsorption element 25 to the first magnetic adsorption element 12 and prevents damage to the surface of the electronic device.
[0036] The second magnetic adsorption element 25 and the first magnetic adsorption element 12 can also be converted into magnetic pole pieces or magnets, but are not limited to the method of the present invention. The second magnetic adsorption element 25 magnetically adsorbs the first magnetic adsorption element 12 and provides auxiliary fixing force, and also helps the surrounding multiple locking members 24 to enter the mounting groove chamber 13 and lock to the inner edge of the surrounding wall 11, thereby ensuring the integrity of the locking state.
[0037] The abutment portion 23 is a cylindrical housing formed in the central region of the support seat 21 and projecting outward, the diameter of which is smaller than the diameter of the opening in the surrounding wall 11, and the abutment portion 23 has a plurality of windows 231, which are distributed radially and at equal angles on the circumferential wall of the abutment portion 23. The locking member 24 extends through the windows 231 and is linearly movable within the windows 231. The locking member 24 has an outward-facing side wall 241, the top of which has an outward-projecting hook block 242, the hook block 242 being inclined.
[0038] When the locking member 24 moves to the inside of the window portion 231, the hook block 242 retracts into the outer wall 232 of the abutment portion 23, becoming unlocked. When the locking member 24 moves to the outermost position of the window portion 231, both the hook block 242 and the side wall 241 protrude from the outer wall 232 of the abutment portion 23, becoming locked. Another special feature of this design is that the diameter formed by the two symmetrically positioned side walls 241 is larger than the diameter of the outer wall 232. The purpose of this is to prevent oscillation and increase the locking effect by having the side walls 241 contact the vertical wall of the opening of the enclosure wall 11 in the locked state, so that the first joining member 10 and the second joining member 20 rotate relative to each other and fix their positions.
[0039] As shown in Figures 3 and 4, in this embodiment, a bottom casing 27 is further provided at the bottom of the support seat 21, and the two are locked together with screws 271, forming a housing space between the support seat 21 and the bottom casing 27, which is used to house a plurality of locking members 24, an interlocking member 28, and a part of the structure of the operating member 22.
[0040] The function of the housing space is to allow the multiple locking members 24 to move only linearly in the radial direction at the abutting portion 23, to restrict the interlocking member 28 to the support seat 21 and to move up and down only in the axial direction, and the operating member 22 is pivotally attached to the bottom casing 27, the operating member 22 drives the up and down of the interlocking member 28, and the interlocking member 28 controls the retraction of the locking members 24 to the abutting portion 23 by pressing the operating member 22 by extending or retracting the locking members 24 from the abutting portion 23 during the up and down process.
[0041] Next, the interlocking relationships and structure of each component will be described. The butt joint 23 has a plurality of window portions 231 distributed at equal angles on its circumferential wall, and inside the butt joint 23, a plurality of partition plates 233 are provided at positions corresponding to the window portions 231, and its central region has a guide column 234 extending downward. Each locking member 24 is installed between the corresponding partition plates 233, ensuring a linear path for movement, and allowing the hook block 242 and a portion of the side wall 241 to extend through the window portions 231.
[0042] The bottom casing 27 is also provided with a plurality of baffles 272 at positions corresponding to the window portion 231 and the partition plate 233. These baffles 272 are used to limit the downward position of the locking member 24 and, in combination with the partition plate 233, ensure that the locking member 24 can move linearly in the radial direction.
[0043] A first groove 243 is further formed on the side of the locking member 24 away from the side wall 241, and each of the first grooves 243 is used to mount a first spring 244, and as shown in Figure 2, after assembly, one end of the first spring 244 is pressed against the inner wall of the first groove 243 and the other end is pressed against the guide column 234, so that in the absence of external force, a portion of the locking member 24 extends out of the abutment portion 23.
[0044] The interlocking member 28 has a guide hole 281 in its center into which the guide column 234 is inserted, thereby allowing the interlocking member 28 to move up and down only along the axial direction of the guide column 234. In this embodiment, the guide hole 281 is a non-circular hole and is shaped to match the shape of the guide column 234. There are further inclined guide grooves 282 around the guide hole 281, into which an inclined guide member 245 extending downward from the locking member 24 is inserted, and both the inclined guide grooves 282 and the inclined guide member 245 are in inclined contact with each other.
[0045] As shown in Figure 5, as the interlocking member 28 rises, the position of the inclined guide groove 282 also gradually rises, thereby allowing the locking member 24 to be retracted into the abutting portion 23. The interlocking member 28 is also provided with two fixing members 283 at symmetrical positions, and a second spring 284 can be attached to each fixing member 283. After assembly, one end of the second spring 284 is pressed against the fixing member 283, and the other end is pressed against the inner wall of the support seat 21, causing the interlocking member 28 to return to its lowest position when there is no external force.
[0046] The operating member 22 is pivotally attached to the bottom casing 27, and the operating member has a lift block 221 inside the bottom casing 27, and a notch 222 is formed in the center of the lift block 221, which is provided for the guide column 234 to pass through.
[0047] As shown in Figure 2, after assembly, the lift block 221 contacts the bottom of the interlocking member 28, and as shown in Figure 5, when the user presses the operating member 22, the rotation axis of the operating member 22 is in an intermediate position, so the lift block 221 rises and pushes up the interlocking member 28, causing the interlocking member 28 to rise, and furthermore, due to the inclined guide groove 282 and its combination with the inclined guide member 245, the multiple locking members 24 retract into the abutting portion 23.
[0048] When the external force disappears, the locking member 24 returns to its extended state due to the action of the first spring 244, and the interlocking member 28 returns to its original position due to the action of the second spring 284. This achieves the objective of releasing the lock simply by pressing the operating member 22 with one hand.
[0049] The quick-release locking mechanism with magnetic positioning function of this invention has been applied to conventional electronic equipment brackets on bicycles or motorcycles. Since bicycles or motorcycles are prone to severe vibrations when they encounter uneven outdoor surfaces, this invention further incorporates a set of vibration isolation systems within the structure to reduce damage to electronic equipment caused by vibration.
[0050] As shown in Figure 6, the support seat 21 is attached to the bottom seat 29 in a manner that allows it to be elastically raised and lowered, and as shown in Figure 4, the structure has a plurality of stopper columns 211 that extend downward from the support seat 21, and the stopper columns 211 are distributed in the outer peripheral region of the bottom casing 27 so as not to prevent the bottom casing 27 from being connected to the support seat 21 by screws 271.
[0051] Furthermore, a plurality of elastic members 212 are provided to be fitted around the outer circumference of the stopper column 211, and these elastic members 212 are compression springs. As shown in Figure 3, the base 29 is provided with a plurality of fitting holes 291 and a plurality of mounting screws 292, the diameter of which is larger than the diameter of the stopper column 211 and smaller than the maximum diameter of which is smaller than which is smaller than which is smaller than which is larger the mounting screws 292. The mounting assembly method is as follows: First, the elastic members 212 are fitted around the outer circumference of the stopper column 211, the stopper column 211 is inserted into the fitting holes 291, and the mounting screws 292 are locked to the stopper column 211 via the outside of the base 29.
[0052] In this way, the elastic member 212 is compressed between the support seat 21 and the base seat 29, and the mounting screw 292 limits the furthest distance between the support seat 21 and the base seat 29. When an external force is applied to the support seat 21, the action of the elastic member 212 and the stopper column 211 can pass through the fitting hole 291, thereby achieving a good seismic isolation effect.
[0053] Furthermore, in order to enhance the seismic isolation effect of this invention, as shown in Figures 7, 8, and 9, another set of auxiliary seismic isolation structures 30 can be attached to the base 29, achieving optimal seismic isolation with two sets of double seismic isolation structures.
[0054] The auxiliary seismic isolation structure 30 includes a support member 31, a plurality of cushioning members 32, a connecting member 33, and a plurality of locking screws 34. The plurality of cushioning members 32 are installed between the support member 31 and the connecting member 33, and the locking screws 34 are used to sequentially pass through the connecting member 33, the cushioning members 32, and the support member 31, and are finally locked to the bottom surface of the base 29. The seismic isolation effect can be adjusted by controlling the amount of compression of the cushioning members 32 by the degree to which the locking screws 34 are tightened.
[0055] The support member 31 has a plurality of protruding guide pipes 311, and the support member 31 forms corresponding recessed engagement grooves 312 around each guide pipe 311. The outer shape of the cushioning member 32 is an arc-shaped hollow elastic body, and its material is rubber or an elastic cushioning material, and the center of the cushioning member 32 has a through passage 321, and both ends of the passage 321 have a neck portion 322 and a protruding portion 323 on the outer circumference of the cushioning member 32, the protruding portion 323 protruding from the surface of the cushioning member 32, its size and shape corresponding to the engagement groove 312, the neck portion 322 being the smallest outer diameter portion and used for locking into the connecting member 33.
[0056] The connecting member 33 has a plurality of mounting holes 331, and each mounting hole 331 has a locking ring 332 that protrudes toward the center of the hole, and the locking ring 332 can be locked into the neck portion 322 during assembly. Since the connecting member 33 is a component that combines with other components, the shape of the connecting member 33 can be freely changed as needed, and in this embodiment, the central region of the connecting member 33 has a spherical joint 333, the function of the spherical joint 333 will be described later.
[0057] During assembly, the support member 31 passes through the passage 321 of the buffer member 32 via the guide pipe 311 and positions the protruding portion 323 within the engagement groove 312, the connecting member 33 is locked within the neck portion 322 with the locking ring 332, and the locking screw 34 passes through the tube of the guide pipe 311 and is finally locked into the screw hole 293 on the bottom surface of the base seat 29, thereby completing the assembly of the auxiliary seismic isolation structure 30.
[0058] Figure 10 shows the actual usage of the present invention. The present invention is a quick-release locking mechanism having a magnetic positioning function that is fixed to a motorcycle or bicycle via a support bracket 40. This embodiment provides only one structure and is not limited to the use of only this structure. As described above, the support seat 21 of the present invention is attached to the base seat 29 in an elastically elevating manner and is coupled by the base seat 29 to the auxiliary seismic isolation structure 30, the auxiliary seismic isolation structure 30 is provided with the spherical joint 333. The support bracket 40 includes the support component 41 and the fixing component 42.
[0059] The support component 41 includes a first retaining member 411, a second retaining member 412, and a locking member 413. The first retaining member 411 and the second retaining member 412 are clamped together in the middle by bolts of the locking member 413. By rotating the locking member 413, the first retaining member 411 and the second retaining member 412 can be brought into contact with each other and locked. Both ends of the first retaining member 411 and the second retaining member 412 are hemispherical grooves. The spherical joint 333 is clamped by the first retaining member 411 and the second retaining member 412, achieving the purposes of angle adjustment and fixing.
[0060] The fixing component 42 includes a first arc-shaped member 421 and a second arc-shaped member 422, the first and second arc-shaped members 421 and 422 being semi-circular in shape, and can be fixed to the outer wall of a circular mounting member after being joined together, the mounting member being, for example, a motorcycle connecting rod, support rod, or handle. The connection structure between the first arc-shaped member 421 and the second arc-shaped member 422 is connected by a pivot at one end of the abutting portion, and the other end is locked with a fixing bolt 423 to achieve the required fixation. Furthermore, a spherical projection member 424 is provided on the outer wall of the first arc-shaped member 421, and the spherical projection member 424 is provided for clamping by the first retaining member 411 and the second retaining member 412, thereby achieving the purposes of angle adjustment and fixing.
[0061] In summary, the first joining member 10 can be fixed to the back of the mobile phone 50 in advance by an adhesive method, the connecting bracket 40 can be fixed to the handlebars or support frame of a motorcycle or bicycle, and the user can align the mounting groove chamber 13 with the abutting portion 23 and then press to retract the locking member 24, which then extends, thereby locking it to the inner edge of the enclosure wall 11 and mechanically locking the second joining member 20 and the first joining member 10, and the second magnetic adsorption element 25 can magnetically adsorb the first magnetic adsorption element 12 to provide auxiliary fixing force and ensure that the locked state of both the first joining member 10 and the second joining member 20 is maintained.
[0062] When a user attempts to remove an electronic device, they can press the operating member 22 with just one hand, retracting the locking member 24 via the internal transmission structure, releasing the locking member 24 from the enclosure 11, and the second connecting member 20 can quickly detach from the first connecting member 10. The design of this invention allows for quick locking when the user intends to use the device and one-handed operation when they wish to release the lock, achieving the necessary convenience and operational efficiency.
[0063] The above descriptions are merely preferred embodiments of the present invention and are not intended to limit the scope of the embodiments of the present invention. In other words, equivalent changes and modifications based on the claims for registration of the utility model of the present invention are all included within the scope of the present invention. [Explanation of symbols]
[0064] 10: First joint member 11: Enclosure 111: Conical slope 12: First magnetic adsorption element 13: Mounting groove chamber 20: Second joint member 21: Support seat 211: Stopper Pillar 212: Elastic member 22: Operating component 221: Lift Block 222: Notch 23: Butt joint 231: Window section 232: Exterior wall 233: Partition plate 234: Guidepost 24: Locking member 241: Side wall 242: Hook Block 243: The First Groove 244: First spring 245: Inclined guide member 25: Second magnetic adsorption element 26: Cushion 27: Bottom casing 271: Screw 272: Baffle 28: Interlocking member 281: Guide hole 282: Inclined guide groove 283: Fixing member 284: Second spring 29: Bottom seat 291: Fitting hole 292: Mounting screws 293: Screw hole 30: Auxiliary seismic isolation structure 31: Support member 311: Guide pipe 312: Engagement groove 32: Cushioning material 321: Passageway 322: Neck section 323:Protrusion 33: Connecting member 331: Mounting hole 332: Locking ring 333: Spherical joint 34: Locking screws 40: Support bracket 41: Support component 411: First retaining member 412: Second retaining member 413: Locking component 42: Fixed components 421: First arc-shaped member 422: Second arc-shaped member 423: Fixing bolt 424: Spherical protruding member 50: Mobile phone
Claims
1. A quick-release lock mechanism having a magnetic positioning function, A first joining member having an enclosure wall, the enclosure wall surrounding a hollow mounting groove chamber in an annular shape, and provided with at least one first magnetic adsorption element, The device includes a support seat and an operating member, the support seat having a convex abutment portion, a plurality of extendable or retractable locking members provided around the abutment portion, and the support seat having at least one second magnetic adsorption element in the outer peripheral region of the abutment portion, the position of the second magnetic adsorption element corresponding to the first magnetic adsorption element, and the operating member having a second connecting member installed on the support seat and interlocked with the locking member, A quick-release locking mechanism in which, when the abutting portion enters the mounting groove chamber, the multiple locking members are locked to the inner edge of the enclosure wall, and an auxiliary fixing force is generated by the mutual attraction between the second magnetic adsorption element and the first magnetic adsorption element, and furthermore, by operating the operating member, the locking members can be retracted into the abutting portion in conjunction with each other, thereby releasing the locked state.
2. The quick-release lock mechanism having a magnetic positioning function according to claim 1, wherein the abutting portion is a cylindrical housing formed in the central region of the support seat and protruding outward, and the diameter of the abutting portion is smaller than the diameter of the opening of the surrounding wall.
3. The quick-release locking mechanism having a magnetic positioning function according to claim 2, wherein the circumferential outer wall of the abutting portion has a plurality of windows, each locking member is restricted in the corresponding window and is movable or extendable in the radial direction, each locking member has an outward-facing side wall, the top of which has an outward-projecting slanted hook block, and when the plurality of locking members are in a locked state, the diameter formed by two symmetrically positioned side walls is greater than the diameter of the outer wall of the abutting portion.
4. The quick-release lock mechanism having a magnetic positioning function according to claim 1, wherein the operating member is interlocked with the locking member via a transmission structure inside the support seat, a bottom casing is further provided at the bottom of the support seat, a housing space is formed between the support seat and the bottom casing, and a plurality of the locking members, interlocking members and a part of the structure of the operating member are housed in the housing space.
5. The quick-release lock mechanism having a magnetic positioning function according to claim 4, wherein the interlocking member within the support seat is movable up and down only in the axial direction, the interlocking member is provided with a plurality of inclined guide grooves, each locking member is provided with an inclined guide member and is inserted into the corresponding inclined guide groove, the operating member is pivotally attached to the bottom casing and has a lift block that contacts and interlocks with the interlocking member, the operating member drives the interlocking member to move in the axial direction, and the locking member is moved radially by the interlocking member.
6. A quick-release locking mechanism having a magnetic positioning function according to claim 5, wherein a plurality of first springs are provided inside the abutting portion, each of the first springs in contact with the corresponding locking member, and the first springs provide an elastic force that extends the locking member outward.
7. The quick-release lock mechanism having a magnetic positioning function according to claim 5, wherein at least one second spring is provided within the support seat, the second spring is in contact with the interlocking member, and the second spring provides an elastic force to return the interlocking member to its original position.
8. The quick-release lock mechanism having a magnetic positioning function according to claim 1, wherein the support seat is attached to the base in a manner that allows it to be elastically raised and lowered, at least one elastic member is provided between the support seat and the base, and the support seat is capable of cushioning displacement relative to the base.
9. The quick-release lock mechanism having a magnetic positioning function according to claim 8, wherein the support seat has a plurality of stopper columns extending downward, and compression springs which are elastic members are fitted around the outer circumference of the stopper columns, the bottom seat is provided with a plurality of fitting holes through which the stopper columns pass, and a plurality of mounting screws are screwed onto the stopper columns so that the furthest distance between the support seat and the bottom seat is limited and the elastic members are compressed between them.
10. The base is further provided with an auxiliary seismic isolation structure, the auxiliary seismic isolation structure includes a support member, a connecting member, and a plurality of buffer members sandwiched between the two, and the auxiliary seismic isolation structure together with the elastic member constitutes a double seismic isolation mechanism, the quick-release lock mechanism having a magnetic positioning function according to claim 8.
11. The auxiliary seismic isolation structure further includes a plurality of locking screws, the plurality of buffer members are installed between the support member and the connecting member, the locking screws pass sequentially through the connecting member, the buffer members and the support member and lock onto the bottom surface of the base, and the pre-compression ratio of the buffer members can be controlled by adjusting the degree of fastening of the locking screws, thereby further adjusting the seismic isolation damping effect, the quick-release locking mechanism having a magnetic positioning function according to claim 10.