Mount having high adaptability
By designing a detachable mounting base and multiple connection methods, the problem of insufficient adaptability of existing brackets is solved, achieving stable connection and flexible installation in various scenarios, suitable for vehicle, home, office and outdoor scenarios.
Patent Information
- Authority / Receiving Office
- WO · WO
- Patent Type
- Applications
- Current Assignee / Owner
- SHENZHEN BASEUS TECH CO LTD
- Filing Date
- 2025-12-16
- Publication Date
- 2026-07-09
AI Technical Summary
The existing brackets are not adaptable enough, especially when the fixed seat is connected to the vehicle body, the stability is poor, and they cannot meet the installation requirements of external components in various scenarios.
Design a highly adaptable bracket, including a detachable first fixing seat and a second fixing seat. Through various matching methods such as magnetic attraction, snap-fit, and thread, it can be connected as a whole in the first state and separated in the second state to adapt to the installation needs of different scenarios.
The bracket has improved stability and adaptability, enabling it to securely connect external components in various scenarios. It is suitable for installation in confined spaces or specific locations, enhancing the flexibility and stability of the connection. It is applicable to in-vehicle, home, office, and outdoor scenarios.
Smart Images

Figure CN2025142899_09072026_PF_FP_ABST
Abstract
Description
Highly adaptable support Technical Field
[0001] This application relates to the field of stent technology, and in particular to a highly adaptable stent. Background Technology
[0002] With the widespread use of mobile devices, phone stands, as an auxiliary tool, have been widely used in various scenarios such as car navigation, video shooting, and office meetings. Existing phone stands are usually fixed to external devices (such as dashboards, desktops, and stand poles) by clamping or adsorption to achieve stable support for mobile phones or other mobile devices.
[0003] In existing technologies, the core structure of a bracket includes a support portion for connecting electronic devices and a mounting base for fixing it to other components. Taking a vehicle-mounted bracket as an example, to ensure the stability of the mounting base's connection to the vehicle body, the mounting base is often made relatively large. However, when the mounting base is assembled and connected to a specific location on the vehicle body, the reliability of the connection between the mounting base and the vehicle body is poor due to the limitations of that specific structure (such as recesses in the center console and air conditioning vents), resulting in poor stability of the bracket supporting the electronic devices. In summary, the adaptability of brackets in existing technologies is insufficient. Summary of the Invention
[0004] Some embodiments of this application propose a highly adaptable bracket suitable for detachably connected electronic devices. The highly adaptable bracket includes:
[0005] The carrier section is used to connect electronic devices;
[0006] The fixing part connects to the bearing part. The fixing part includes a first fixing seat and a second fixing seat. The first fixing seat connects to the bearing part and is adapted to connect to external components. The second fixing seat connects to the bearing part and is adapted to connect to external components.
[0007] The highly adaptable bracket has a first state and a second state. In the first state, the first fixing seat and the second fixing seat are connected to each other, and in the second state, the first fixing seat and the second fixing seat are separated from each other.
[0008] According to the above embodiments, the beneficial effects of this application are:
[0009] The highly adaptable bracket of this application includes a support portion and a fixing portion. The support portion is used to connect electronic devices, and the fixing portion is connected to the support portion and adapted to connect external components. The fixing portion includes a first fixing seat and a second fixing seat. The first fixing seat is connected to the support portion and adapted to connect external components, and the second fixing seat is also connected to the support portion and adapted to connect external components. The highly adaptable bracket has a first state and a second state. In the first state, the first fixing seat and the second fixing seat are connected to each other, and in the second state, the first fixing seat and the second fixing seat are separated from each other.
[0010] The first and second fixing bases of this application can be flexibly switched between the first and second states. When bearing heavy electronic devices, the first and second fixing bases are connected to external components at the same time to ensure a firm connection. When there is insufficient area for external components to be connected, the first and second fixing bases can be separated, with only one of them used to connect to the external components, while the other can be connected to other areas of the external components or left idle. Therefore, this application has high adaptability and can connect external components in various scenarios. Attached Figure Description
[0011] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.
[0012] Figure 1 is a three-dimensional structural diagram of a highly adaptable support as viewed from a first perspective in one embodiment of this application;
[0013] Figure 2 is a three-dimensional structural diagram of the highly adaptable support in Figure 1 as viewed from a second perspective;
[0014] Figure 3 is a schematic diagram of the cross-sectional structure of the highly adaptable support in Figure 1 cut by the first plane;
[0015] Figure 4 is an enlarged view of point A in Figure 3;
[0016] Figure 5 is a schematic diagram of the exploded structure of the highly adaptable support in Figure 2;
[0017] Figure 6 is a three-dimensional structural diagram of the highly adaptable bracket as viewed from a second perspective in another embodiment of this application;
[0018] Figure 7 is a three-dimensional structural diagram of the highly adaptable support in Figure 6 as viewed from a third-person perspective.
[0019] Figure 8 is a schematic diagram of the cross-sectional structure of the highly adaptable support in Figure 6 cut by the second plane;
[0020] Figure 9 is an enlarged view of section B in Figure 8;
[0021] Figure 10 is a three-dimensional structural diagram of a highly adaptable bracket viewed from a fourth perspective in one embodiment of this application, intended to illustrate the first clamping structure and the second clamping structure.
[0022] Figure 11 is a three-dimensional structural diagram of the first fixing seat when the highly adaptable bracket is in the retracted state according to an embodiment of this application.
[0023] Figure 12 is a schematic diagram of the cross-sectional structure of the first fixed seat in Figure 11 cut by the third plane;
[0024] Figure 13 is a three-dimensional structural diagram of the first fixing seat when the highly adaptable bracket is in a clamping state according to an embodiment of this application.
[0025] Figure 14 is a schematic diagram of the cross-sectional structure of the first fixed seat in Figure 13 cut by the fourth plane;
[0026] Figure 15 is a schematic cross-sectional view of a highly adaptable bracket cut by a fifth plane in one embodiment of this application, intended to illustrate the design of the suction cup;
[0027] Figure 16 is a three-dimensional structural diagram of the first fixing seat in one embodiment of this application, intended to illustrate the design of the suction cup;
[0028] Figure 17 is a schematic cross-sectional view of the highly adaptable bracket cut by the sixth plane in another embodiment of this application, intended to illustrate the design of the suction cup;
[0029] Figure 18 is a three-dimensional structural diagram of the first fixing seat in one embodiment of this application, intended to illustrate the design of the first snap-fit structure;
[0030] Figure 19 is a three-dimensional structural diagram of the second fixing seat in one embodiment of this application, intended to illustrate the design of the second snap-fit structure;
[0031] Figure 20 is a three-dimensional structural diagram of a highly adaptable support as viewed from a fifth perspective in one embodiment of this application;
[0032] Figure 21 is a schematic diagram of the cross-sectional structure of the highly adaptable support in Figure 20 cut by section aa;
[0033] Figure 22 is an enlarged view of point C in Figure 21;
[0034] Figure 23 is an enlarged view of point D in Figure 21;
[0035] Figure 24 is a three-dimensional structural schematic diagram of a highly adaptable bracket viewed from a sixth perspective in one embodiment of this application, wherein the first fixing seat and the second fixing seat are both housed in the shell;
[0036] Figure 25 is a three-dimensional structural schematic diagram of a highly adaptable bracket viewed from a seventh perspective in one embodiment of this application, wherein the first fixing seat is housed in the shell and the second fixing seat is exposed;
[0037] Figure 26 is a three-dimensional structural schematic diagram of a highly adaptable bracket in one embodiment of this application, viewed from an eighth perspective, wherein both the first fixing seat and the second fixing seat are exposed;
[0038] Figure 27 is a schematic diagram of the structure of a highly adaptable bracket in one embodiment of this application, intended to demonstrate the adjustment of the orientation of electronic devices by bending the intermediate connector;
[0039] Figure 28 is a structural schematic diagram of a highly adaptable bracket in another embodiment of this application, intended to demonstrate the adjustment of the orientation of electronic devices by bending the intermediate connector.
[0040] Reference numerals: 10; 100; 110; 120; 130; 140; 150; 150; 200; 210; 220; 221; 230; 240; 250; 251; 252; 260; 270; 300; 310; 320; 321; 330; 340; 350; 351; 352; 360; 400; 410; 420; 500; 600; 700; First connecting structure 810; through hole 811; second connecting structure 820; clamping member 830; first protrusion 831; box body 900; receiving cavity 910; locking part 1000.
[0041] The realization of the purpose, functional features and advantages of this application will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation
[0042] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this application, and not all of the embodiments. Based on the embodiments of this application, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of this application.
[0043] It should be noted that if the embodiments of this application involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of the components in a specific posture. If the specific posture changes, the directional indicators will also change accordingly.
[0044] Furthermore, if the embodiments of this application involve descriptions such as "first" or "second," these descriptions are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the use of "and / or," "and / or," or "and / or" throughout the text implies three parallel solutions. For example, "A and / or B" includes solution A, solution B, or a solution where A and B are simultaneously satisfied. Furthermore, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. When the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed in this application.
[0045] Referring to Figures 1 to 9, this application proposes a highly adaptable bracket 10, which is suitable for detachably connecting electronic devices. Referring to Figures 1, 5, and 6, the bracket 10 of this application includes a support portion 100, a first fixing base 200, and a second fixing base 300. The support portion 100 is used to connect electronic devices, the first fixing base 200 is connected to the support portion 100, and the first fixing base 200 is adapted to connect external components. The second fixing base 300 is connected to the support portion 100, and the second fixing base 300 is adapted to connect external components.
[0046] It should be noted that "external components" is a general term for the objects to which the bracket of this application is connected. The first fixing seat 200 and the second fixing seat 300 can be connected to the same external component, for example, both can be connected to a table. The first fixing seat 200 and the second fixing seat 300 can also be connected to different external components to assist each other. For example, in the case of limited space, the first fixing seat 200 of this application can be connected to a table, and the second fixing seat 300 can be connected to the side wall of a refrigerator. The two work together to improve the stability of the bracket connected to the external component.
[0047] The highly adaptable bracket 10 has a first state and a second state. The first fixing seat 200 includes a first mating member 220, and the second fixing seat 300 includes a second mating member 320. In the first state, the first mating member 220 is connected to the second mating member 320 so that the first fixing seat 200 and the second fixing seat 300 are connected to each other. In the second state, the first fixing seat 200 and the second fixing seat 300 are separated from each other.
[0048] In summary, the first fixing base 200 and the second fixing base 300 can flexibly switch between a first state and a second state. In the first state, the first fixing base 200 and the second fixing base 300 are interconnected through their respective first mating parts 220 and second mating parts 320, forming a single integrated structure. This design enhances overall stability and is particularly suitable for applications requiring significant weight or additional stability to ensure a secure connection. When the area for connecting external components is insufficient, the first fixing base 200 and the second fixing base 300 can be separated, with only one used to connect to the external component, while the other can be connected to other areas of the external component or left idle. Therefore, this application has wide adaptability and can connect external components in various scenarios. For example, in certain confined spaces or specific installation requirements, it may not be possible to install two fixing bases simultaneously. In this case, using a single fixing base not only saves space but also allows for adjustment of the position and angle of the bracket 10 according to actual needs, meeting diverse application requirements. For instance, for suspended installations or special installation requirements in wall corners, the single fixing base design is particularly practical because it provides more flexible installation options without sacrificing connection stability.
[0049] Furthermore, this application utilizes the synergistic effect between the mounting brackets to enhance stability. Specifically, when two mounting brackets are connected, the connection between them increases the rigidity and torsional resistance of the overall structure. In addition, this design ensures that even if one mounting bracket becomes loose, the other can provide sufficient support, thus guaranteeing the safety of the overall structure. For example, when installing heavy-duty equipment such as large displays or surveillance cameras, the dual-mount design can effectively distribute the load, preventing the equipment from tilting or falling due to uneven stress at a single point. In some embodiments, for applications requiring high stability, such as outdoor electronic billboards or surveillance camera installations, the combined use of the first mounting bracket 200 and the second mounting bracket 300 can effectively prevent the equipment from tilting or falling due to wind or other external forces. Simultaneously, because this design can adapt to various external environments and conditions, it greatly expands the application scenarios of the bracket 10, extending beyond indoor use.
[0050] Regarding the definition of electronic devices, it can be understood that an electronic device can refer to the device itself, such as a bare device like a mobile phone, tablet, computer, or e-reader, or it can refer to a combination of the device itself and a protective case fitted onto the device itself, such as a mobile phone or tablet with a protective case. The carrier part 100 of this application can magnetically attach to the device itself or to the protective case fitted onto the device itself.
[0051] Furthermore, several application scenarios are given below to further illustrate the bracket 10 of this application. For example, in a vehicle scenario, the external component can be the vehicle's onboard platform. The first fixing seat 200 and / or the second fixing seat 300 of the bracket 10 are snapped onto the vehicle's onboard platform via the engaging structure of the support portion 100, thereby facilitating the placement of electronic devices connected to the support portion 100, such as mobile phones and dashcams, within the driver's field of vision for easy viewing of navigation information and monitoring of driving status. In a home environment, the external component can be a wall, refrigerator, etc. For example, when a tablet bracket 10 needs to be fixed on a kitchen wall for viewing recipe videos, the fixing seat of the bracket 10 can be adsorbed onto a smooth magnetic metal material or a wall surface suitable for the suction cup 600 via the suction cup 600 structure of the support portion 100, or it can be glued to the wall using an adhesive structure, allowing the tablet on the support portion 100 to stably display content for easy reference during cooking. For office scenarios, the external component can be the bezel or base of a computer monitor. If it is necessary to fix a mobile phone or other electronic device used for office work next to the monitor, the mounting base of the bracket 10 can be magnetically attached to the magnetic monitor bracket 10 using a magnetic structure, or it can be snapped into a specific groove in the monitor base using a snap-fit structure, so that the electronic device and the monitor form an organic whole, facilitating multitasking, such as checking mobile phone messages while editing documents on the computer. In outdoor scenarios, the external component can be a bicycle handlebar. The mounting base of the bracket 10 can wrap the strap around the handlebar and tighten it through the strap structure of the support part 100, or use a clamping structure to clamp the handlebar, so that electronic devices connected to the support part 100 of the bracket 10, such as action cameras, smartwatches, etc., can record information such as scenery and speed during the ride, and also make it convenient for the cyclist to view relevant data at any time. The examples above are only external components in some scenarios, and this application is not limited to the above content. In the above embodiments, the first fixing seat 200 and the second fixing seat 300 of this application can be combined together and fixed to the external component to ensure that the bracket 10 and the external component are firmly and reliably connected. The first fixing seat 200 and the second fixing seat 300 of this application can also be separated from each other, with only one of them used to be connected to the external component to accommodate installation in a smaller area.
[0052] Specifically, with the assistance of the first mating member 220 and the second mating member 320, the first fixing seat 200 can approach the second fixing seat 300 and eventually abut against each other. The direction in which the first fixing seat 200 approaches the second fixing seat 300 can be arbitrary. For example, when both the first mating member 220 and the second mating member 320 are configured as magnets, the first fixing seat 200 and the second fixing seat 300 can approach each other and abut against each other in the left-right direction, or the first fixing seat 200 and the second fixing seat 300 can be stacked in the up-down direction.
[0053] In some embodiments, the first mating member 220 and the second mating member 320 can have various specific forms. For example, the first mating member 220 and the second mating member 320 can be magnetically designed. Specifically, the first mating member 220 can be a first magnet 221, and the second mating member 320 can be a second magnet 321, and the two have opposite magnetic properties. For example, in the scenario of the vehicle mount 10, the first magnet 221 on the first mounting base 200 and the second magnet 321 on the second mounting base 300 attract each other. When it is necessary to fix the entire mount 10 to the center console of the car, the first mounting base 200 and the second mounting base 300 can be brought close together, so that the first magnet 221 and the second magnet 321 attract each other, thereby tightly connecting the two together to form a stable mount 10, enhancing the overall stability and ensuring the stability of the electronic device during vehicle operation. In some embodiments, if the external component is a flat surface with magnetic metal, such as a metal drawer of an office desk or a refrigerator, the magnet on the first fixing seat 200 or the second fixing seat 300 can be attracted to the metal surface to achieve fixation. At this time, the first mating part 220 (magnet) and the external component (magnetic metal surface) cooperate with each other to play the role of connection and fixation.
[0054] In some embodiments, the first mating member 220 and the second mating member 320 can be a snap-fit design. Specifically, the first mating member 220 can be a protruding snap-fit, and the second mating member 320 can be a corresponding slot. For example, one side of the first fixing base 200 is designed with a small protruding snap-fit, and one side of the second fixing base 300 is designed with a matching slot. When the bracket 10 needs to be stored or in some scenarios where a small size is required, the first fixing base 200 and the second fixing base 300 are aligned so that the snap-fit is inserted into the slot and locked. At this time, the first mating member 220 (snap-fit) and the second mating member 320 (slot) engage with each other, fixing them together for easy carrying and storage. In actual use, if the external component is a dedicated base with a slot, such as the base of some display equipment, the snap-fit on the first fixing base 200 can be inserted into the slot to achieve connection and fixation with the external component.
[0055] In some embodiments, the first mating member 220 and the second mating member 320 can be threaded designs. Specifically, the first mating member 220 can be an external thread, and the second mating member 320 can be an internal threaded hole. For example, in professional photography scenarios, the connecting end of the first mounting base 200 is designed with an external thread, and the connecting end of the second mounting base 300 is designed with an internal threaded hole. When it is necessary to fix the bracket 10 to the camera tripod, the external thread of the first mounting base 200 is tightened to connect with the internal threaded hole of the tripod, and at the same time, the second mounting base 300 is connected to the threaded hole on the camera base. Through the threaded engagement of the first mating member 220 (external thread) and the second mating member 320 (internal threaded hole), a stable connection is achieved between the bracket 10, the camera, and the tripod, ensuring stability during shooting.
[0056] In some embodiments, the first mating member 220 and the second mating member 320 can be a nested design. Specifically, the first mating member 220 can be a protruding cylinder, and the second mating member 320 can be a cylindrical recess. For example, in some deformable electronic device brackets 10, the first fixing seat 200 is designed with a protruding cylinder, and the second fixing seat 300 is designed with a mating recess. When it is necessary to adjust the shape of the bracket 10 to adapt to different scenarios, the protruding cylinder is inserted into the recess, making them nested together. At this time, the first mating member 220 (protruding cylinder) and the second mating member 320 (recess) are nested together, connecting the two together, which makes it convenient for users to adjust the shape of the bracket 10 according to different needs, and achieve fixation at multiple angles and in multiple scenarios.
[0057] Referring to Figures 1, 2, and 5, in some embodiments, the highly adaptable bracket 10 includes an intermediate connector 400, a first fixing seat 200 connected to one end of the intermediate connector 400, a second fixing seat 300 connected to the other end of the intermediate connector 400, and a support portion 100 connected to the intermediate connector 400, with the support portion 100 located between the first fixing seat 200 and the second fixing seat 300 along the extending direction of the intermediate connector 400. With this design, the intermediate connector 400 of this application is inserted through the support portion 100, and the first fixing seat 200 and the second fixing seat 300 are respectively connected to both ends of the intermediate connector 400. When the first fixing seat 200 and the second fixing seat 300 cooperate to connect external components, both the intermediate connector 400 between the first fixing seat 200 and the support portion 100 and the intermediate connector 400 between the second fixing seat 300 and the support portion 100 provide support for the support portion 100, ensuring the stability of the bracket 10 during use. When either the first fixing seat 200 or the second fixing seat 300 is connected to an external component, the intermediate connector 400, which is used only to connect the fixing seat to the external component and the load-bearing part 100, provides support to the load-bearing part 100. This design combines flexibility and load-bearing capacity, allowing users to choose flexibly according to actual usage scenarios. The bracket 10 of this application has strong compatibility.
[0058] Understandably, the intermediate connector 400 can be a deformable steel rope, which is threaded through the bearing portion 100, with its two ends connected to the first fixing seat 200 and the second fixing seat 300, respectively. Alternatively, the intermediate connector 400 can be two steel ropes. In this design, one end of each rope is connected to either the first fixing seat 200 or the second fixing seat 300, and the other end is connected to the bearing portion 100. From an external structural perspective, the steel rope appears to be threaded within the bearing portion 100. Of course, the intermediate connector 400 can also be made of other materials and structures.
[0059] Referring to Figures 24 to 26, in some embodiments, the support portion 100 can slide relative to the intermediate connector 400 along the extending direction of the intermediate connector 400, that is, the specific arrangement position of the support portion 100 on the intermediate connector 400 can be flexibly adjusted. Since the support portion 100 is used to connect electronic devices, the electronic devices can be arranged in multiple positions to meet the needs of different application scenarios.
[0060] In some embodiments, the support portion 100 is rotatable relative to the intermediate connector 400. For ease of description and understanding of the specific rotation configuration of the support portion 100, the extension direction of the intermediate connector 400 in a straight state is defined as the first direction. The support portion 100 is rotatable relative to the intermediate connector 400 about an axis parallel to the first direction. It can be understood that the support portion 100 can rotate relative to the intermediate connector 400 in a clockwise direction or in a counterclockwise direction.
[0061] In this design, the support portion 100 can rotate relative to the intermediate connector 400, thereby adjusting the support angle of the support portion 100 on the electronic device. This design can meet various support requirements and reduce the possibility of poor stability of the support portion 100 on the electronic device due to excessive bending of the intermediate connector 400, effectively ensuring the reliability of the bracket 10 in supporting the electronic device.
[0062] Referring to Figures 24 to 26, in some embodiments, the highly adaptable bracket 10 further includes a locking portion 1000, which is used to lock the support portion 100 and the intermediate connector 400. Specifically, the locking portion 1000 is connected to both the support portion 100 and the intermediate connector 400, and has a locked state and an unlocked state. When the locking portion 1000 is in the locked state, it can restrict the movement of the support portion 100 relative to the intermediate connector 400, so that the support portion 100 is stably maintained at a specific position relative to the intermediate connector 400; when the locking portion 1000 is in the unlocked state, it can release the restriction on the support portion 100, so that the support portion 100 can slide or rotate relative to the intermediate connector 400, thereby adjusting its arrangement position. This locking portion 1000 can realize the locking and unlocking operations between the support portion 100 and the intermediate connector 400, which not only improves the stability of the bracket 10 in supporting electronic devices, but also facilitates the adjustment of the support position of electronic devices.
[0063] In some embodiments, the locking part 1000 includes a lock head, a lock seat, and a lock body. The lock body is connected to the support part 100. The lock head and lock seat are partially disposed inside the lock body, and a portion of the intermediate connecting member 400 is disposed between the lock head and the lock seat. The lock head can be brought close to the lock seat to clamp the intermediate connecting member 400 for locking, or moved away from the lock seat to release the intermediate connecting member 400. In other embodiments, the locking part 1000 includes a screw and a threaded sleeve. The threaded sleeve is connected to the support part 100, and the intermediate connecting member 400 passes through the threaded sleeve. Locking and releasing the intermediate connecting member 400 can be achieved by turning the screw. In other embodiments, the locking part 1000 is a fixing clamp connected to the support part 100. Its two clamping ends can be brought close to each other to clamp the intermediate connecting member 400 for locking, or moved away from each other to release the intermediate connecting member 400. The specific structure of the locking part 1000 can be flexibly set according to actual needs.
[0064] Further referring to Figures 1, 2, and 5, the intermediate connector 400 includes a first connector 410 and a second connector 420. Along the extending direction of the first connector 410, the first connector 410 has two relatively distributed ends. One end of the first connector 410 is connected to the first fixing seat 200, and the other end is connected to the bearing portion 100. Along the extending direction of the second connector 420, the second connector 420 has two relatively distributed ends. One end of the second connector 420 is connected to the bearing portion 100, and the other end is connected to the second fixing seat 300. In this embodiment, the intermediate connector 400 is in the form of two segments, namely the first connector 410 and the second connector 420. Therefore, the first connector 410 and the second connector 420 can be flexibly configured according to actual usage scenarios, such as adjusting the length and rigidity of the first connector 410 and the second connector 420 to adapt to different usage occasions.
[0065] Specifically, in some embodiments, to further enhance the adaptability of the intermediate connector 400, the first connector 410 and the second connector 420 can be designed with adjustable lengths. For example, both the first connector 410 and the second connector 420 are configured as telescopic rod structures, each telescopic rod consisting of multiple tubular components whose length can be adjusted via threads or snaps. This design allows users to flexibly adjust the height and angle of the bracket 10 according to actual needs to accommodate electronic devices of different sizes and shapes. Furthermore, to improve the tensile strength and durability of the intermediate connector 400, reinforcing ribs can be added internally or high-strength materials such as carbon fiber composites can be used. For example, the outer layer of the first connector 410 and the second connector 420 is made of aluminum alloy, while the inner core is made of carbon fiber, ensuring both lightweight design and improved mechanical strength. This not only increases the service life of the bracket 10 but also improves its reliability in complex environments.
[0066] Referring to Figures 1 to 5, in some embodiments, the intermediate connector 400 is configured to be flexible, allowing the support portion 100 to face different directions for user convenience. The intermediate connector 400 is made of a material with a certain degree of elasticity, such as spring steel 700 or a metal alloy with memory function. When an external force is applied, the intermediate connector 400 can bend and deform, returning to its original shape after the external force is removed. This characteristic allows the support portion 100 to adjust its angle as needed, facilitating user viewing of the electronic device screen from different perspectives. The advantage of this design is that even in uneven or space-constrained environments, a suitable viewing angle can be found, greatly enhancing the user experience.
[0067] In some embodiments, to provide greater flexibility, the intermediate connector 400 can be designed as a multi-segment structure, with each segment connected by a rotary joint. For example, the intermediate connector 400 can be divided into three segments, each connected by a universal joint, which not only allows for bending deformation but also enables omnidirectional angle adjustment. For instance, users can adjust the angles between the segments to obtain the optimal viewing position, whether standing, sitting, or lying down. Furthermore, an anti-slip coating or texture can be added to the surface of the intermediate connector 400 to increase friction and prevent slippage during use. For example, coating the outer surfaces of the first connector 410 and the second connector 420 with a layer of silicone material provides a good feel and increases grip, ensuring the stability of the bracket 10 on various surfaces.
[0068] Referring to Figures 1 to 5, in some embodiments, the support portion 100 includes a housing 110 and a top cover. The housing 110 and the top cover together define a receiving cavity 130 for receiving one end of the first connector 410 and the second connector 420 facing the support portion 100. Specifically, one end of the first connector 410 extends into the receiving cavity 130 and is securely connected to the support portion 100, and the second connector 420 extends into the receiving cavity 130 and is securely connected to the support portion 100. Specifically, the support portion 100 includes a fixing block 140 disposed within the receiving cavity 130. After the first connector 410 or the second connector 420 extends into the receiving cavity 130, the first connector 410 and the second connector 420 are fixed to the fixing block 140 by screws to achieve connection with the support portion 100. This design makes the entire bracket 10 structure compact and stable, while also facilitating assembly and disassembly. By concealing portions of the first connector 410 and the second connector 420 within the receiving cavity 130, the external exposed portions are reduced, which not only improves aesthetics but also makes the structure compact, stable, and reliable.
[0069] In some embodiments, the housing 110 is further provided with a ring magnet, which is used for magnetic adsorption of electronic devices.
[0070] Referring to Figures 3 to 5, as well as Figures 8 and 9, in some embodiments, the first mating member 220 includes a first magnet 221, and the second mating member 320 includes a second magnet 321. The first magnet 221 and the second magnet 321 have opposite magnetic properties, so that the first magnet 221 and the second magnet 321 can attract each other to connect the first fixing seat 200 and the second fixing seat 300 to each other, and the first fixing seat 200 and the second fixing seat 300 can be easily separated from each other.
[0071] Specifically, in some embodiments, the first magnet 221 is adapted to magnetically attract the second magnet 321. In some embodiments, the first magnet 221 is adapted to magnetically attract an external component. In some embodiments, the second magnet 321 is adapted to magnetically attract an external component. With this design, no additional structures are required; the bracket 10 of this application can be magnetically attracted to an external component solely by the magnetism of the first magnet 221 and the second magnet 321, and the first fixing seat 200 and the second fixing seat 300 can switch between a first state and a second state.
[0072] Taking a specific application scenario as an example, the bracket 10 of this application can be magnetically attached to a refrigerator. Considering that the bracket 10 is relatively small and would be inconvenient to find later after being stored away, the bracket 10 of this application can be magnetically attached to the surface of some magnetic objects when not in use, and placed in a conspicuous place for easy retrieval by the user, such as on the refrigerator door.
[0073] Referring to Figure 5, in some embodiments, the first fixing seat 200 has a first groove 210 recessed on the side facing the second fixing seat 300, and the first magnet 221 is disposed in the first groove 210. The second fixing seat 300 has a second groove 310 recessed on the side facing the first fixing seat 200, and the second magnet 321 is disposed in the second groove 310. This design allows the magnets to be securely embedded in the fixing seats, and in the first state, the two magnets are tightly joined together, thereby achieving a firm connection between the first fixing seat 200 and the second fixing seat 300. The design of the first groove 210 and the second groove 310 not only helps with precise alignment but also prevents the magnets from shifting or falling off during use. When the bracket 10 is in the second state, that is, when the first fixing seat 200 and the second fixing seat 300 are separated, each fixing seat can still work independently, ensuring the applicability of the bracket 10 in different scenarios.
[0074] The first groove 210 and the second groove 310 can be circular or square in shape to accommodate the geometry of the magnet, while ensuring an appropriate gap between the magnet and the groove wall for easy installation and removal. For example, the first groove 210 can be designed as a square recess with a diameter slightly larger than that of the first magnet 221, and the second groove 310 can be adjusted accordingly based on the specific dimensions of the second magnet 321. This design ensures effective magnet attraction while providing sufficient space for fine-tuning, improving the flexibility and reliability of the overall assembly.
[0075] Understandably, in some embodiments, to further enhance the magnet's adsorption effect and durability, a non-conductive material, such as a polytetrafluoroethylene (PTFE) coating, can be added to the inner surfaces of the first groove 210 and the second groove 310. This coating not only reduces friction but also effectively isolates moisture and dust from the external environment, protecting the magnet from corrosion. For example, such protective measures are particularly important for the bracket 10, which is exposed to outdoor environments for extended periods. Alternatively, the magnet can be embedded in a flexible material, such as a silicone sleeve, before being placed in the groove. The advantage of this is that the silicone sleeve can cushion vibrations to some extent, preventing damage to the magnet from impacts.
[0076] In some embodiments, multiple small magnets are combined instead of a single large magnet. For example, the first magnet 221 and the second magnet 321 are each designed as an array of four small cylindrical magnets. These small magnets are arranged in their respective slots according to a certain pattern, forming a uniformly distributed magnetic field region. This method not only enhances the attraction force but also allows for finer adjustments and higher positioning accuracy. For example, by adjusting the arrangement of the small magnets, the magnetic force can be concentrated in a specific direction, thereby optimizing the stability of the entire system.
[0077] Referring to Figures 5 and 9, in some embodiments, the first fixing seat 200 includes a first elastic pad 230 located on the side of the first mating member 220 facing the second fixing seat 300. In the first state, when the first fixing seat 200 and the second fixing seat 300 are connected to each other, the first elastic pad 230 abuts against the second fixing seat 300, providing cushioning and protection. Similarly, the second fixing seat 300 may also be provided with a second elastic pad 330, located on the side of the second mating member 320 facing the first fixing seat 200, and abutting against the first fixing seat 200 in the first state. The presence of the elastic pad not only reduces wear that may be caused by direct contact but also absorbs vibration, providing additional stability and comfort. The elastic pad utilizes its own elasticity and flexibility to disperse pressure and vibration. For example, when the load-bearing part 100 bears a large weight, the elastic pad can relieve some of the stress through deformation, thereby avoiding damage that may be caused by hard contact. In addition, because the elastic pad has good resilience, it can quickly return to its original shape, ensuring reliability and consistency for long-term use.
[0078] Understandably, in some embodiments, polymeric composite materials, such as polyurethane (PU) or thermoplastic elastomers (TPE), can be used to improve the durability and fatigue resistance of the elastic gasket. These materials not only possess excellent abrasion resistance, oil resistance, and aging resistance, but also maintain stable physical properties over a wide temperature range. For example, the hardness of an elastic gasket made of polyurethane can be adjusted according to specific needs, providing sufficient support while ensuring good shock absorption.
[0079] Referring to Figures 6 to 8, in some embodiments, when switching from the second state to the first state, the direction in which the first fixing seat 200 approaches the second fixing seat 300 is the second direction, and the first direction is perpendicular to the second direction. The multi-scenario fixed bracket 10 includes a connecting portion 500, which connects to one side of the first fixing seat 200 along the first direction, and / or the connecting portion 500 connects to one side of the second fixing seat 300 along the first direction. The connecting portion 500 is used to connect external components. The orientation of the side of the connecting portion 500 that connects to the external component is deviated from the direction in which the first fixing seat 200 and the second fixing seat 300 approach each other when the bracket 10 switches from the second state to the first state, to avoid interference.
[0080] Referring to Figures 6 and 7, the way the carrier part 100 connects to electronic devices and / or the form of the fixing part connecting to external components can be achieved by various methods such as magnetic attraction, suction cup 600, thread, buckle, strap, and adhesive to connect with the corresponding objects.
[0081] Specifically, regarding the connection method of the fixing part, in some embodiments, the fixing part includes a magnetic structure. The magnetic structure uses magnetic force to firmly attach the easily stored bracket 10 to a metal external component, such as a car frame or refrigerator door panel. This connection method is not only convenient and quick to install and remove, but also has low requirements for surface flatness, making it suitable for applications requiring frequent position adjustments. In some embodiments, the fixing part includes a suction cup 600 structure. The suction cup 600 structure is suitable for smooth, non-porous surfaces, such as glass windows or mirrors. The suction cup 600 uses atmospheric pressure to adhere tightly to the surface, providing sufficient support to fix the electronic device. When it is necessary to move the easily stored bracket 10, it can be easily removed by gently pulling the release valve. In some embodiments, the fixing part includes a threaded structure. The threaded structure allows the easily stored bracket 10 to be directly screwed into an external component with matching internal threads, such as a bicycle handlebar or tripod top. This connection method is very stable, especially suitable for applications that need to withstand heavy weight or be in a vibrating environment. In some embodiments, the fixing part includes a snap-fit structure. The snap-fit structure allows for quick and easy locking onto external components of specific shapes, such as car air vent grilles or laptop edges. This connection method is simple to operate, requires no tools, and is ideal for temporary or emergency use. In some embodiments, the fixing element includes a strap structure. The strap structure is suitable for cylindrical or other external components that are difficult to fix by other means, such as bicycle handlebars or pipes. The straps are typically made of nylon webbing with quick-release buckles at both ends for easy fastening and unfastening. In some embodiments, the fixing element includes an adhesive structure. The adhesive structure permanently or semi-permanently fixes the easily stored bracket 10 to the external component using strong adhesive or double-sided tape. This method is particularly suitable for installations that require long-term fixation, such as on walls or furniture surfaces.
[0082] Regarding the connection method of the carrier part 100, specifically, in some embodiments, the electronic device can be a tablet, mobile phone, e-reader, etc., and the carrier part 100 connects to the electronic device through magnetic attraction, snap-fit, adhesion, clamping, etc. In this case, the first sidewall is the surface wall of the carrier part 100 that abuts against the back of the tablet, the back of the mobile phone, or the back of the e-reader.
[0083] Referring to Figures 10 to 14, in some embodiments, the first fixing base 200 includes a first main body structure 240 and a first clamping structure 250, and the second fixing base 300 includes a second main body structure 340 and a second clamping structure 350. The first clamping structure 250 is movably connected to the first main body structure 240, allowing it to move relative to the first main body structure 240. In the clamped state, the first clamping structure 250 protrudes from the first main body structure 240 toward the second fixing base 300, enabling the first clamping structure 250 to contact and apply pressure to the external component. Similarly, the second clamping structure 350 is also movably connected to the second main body structure 340 and can protrude toward the first fixing base 200 in the clamped state. Through the design of the clamping structure, the bracket 10 can firmly clamp external components of different sizes and shapes. This design not only improves the adaptability of the bracket 10 but also ensures effective fixation of external components during use.
[0084] In the retracted state, the first clamping structure 250 is close to the first main body structure 240, and the second clamping structure 350 is close to the second main body structure 340, thereby reducing the overall size of the bracket 10 and making it easier to carry and store. When it is necessary to remove the bracket 10 from the external components, separation can be easily achieved by simply moving the clamping structures to the retracted state. This design improves the convenience and flexibility of user operation, while also protecting the external components from damage caused by over-clamping.
[0085] Understandably, in some embodiments, to enhance the stability of the clamping structure, anti-slip material, such as rubber or silicone pads, can be added to the inner sides of the first clamping structure 250 and the second clamping structure 350. These pads not only provide better friction but also prevent scratches to external components. Furthermore, an automatic adjustment mechanism can be designed to automatically adjust the clamping force according to the thickness of the external component to ensure optimal fixation.
[0086] Understandably, in some embodiments, the first clamping structure 250 and the second clamping structure 350 can achieve an automatic reset function via a spring 700. Specifically, each clamping structure is equipped with a small spring 700, which pushes the clamping structure back to its original position when the external force is removed. For example, when the user releases the pressure on the clamping structure, the spring 700 will quickly push it back to the retracted position for easy use next time. This design not only simplifies the user's operation but also increases safety, avoiding the risk of accidentally pinching fingers.
[0087] Referring to Figures 10 to 14, in some embodiments, the first clamping structure 250 includes a first clamping member 251 and a first button 252, both movably connected to the first main body structure 240. The first button 252 is connected to the first clamping member 251 via a mechanical linkage mechanism, such as a spring 700. When the first button 252 is pressed, the first clamping member 251 moves away from the first main body structure 240, thereby releasing the clamping force. The design of the second clamping structure 350 is similar to that of the first clamping structure 250, including a second clamping member 351 and a second button 352, also movably connected to the second main body structure 340. When the second button 352 is pressed, the second clamping member 351 also moves away from the second main body structure 340 accordingly. This design facilitates user operation, allowing for easy clamping and releasing actions.
[0088] In some embodiments, the mechanical linkage mechanism between the button and the clamping element operates based on the lever principle. The force generated by pressing the button is transmitted to the clamping element through the lever, causing it to move outward against the resistance of the internal spring 700. This design ensures effective clamping and release even on larger external components, greatly expanding the application scenarios of the bracket 10.
[0089] Understandably, in some embodiments, a more ergonomic button design can be employed to improve the ergonomic feel of the gripper. For example, the button surface can be textured or covered with a soft material to make pressing more comfortable. Furthermore, a haptic feedback system can be introduced, whereby the button provides a slight vibration to the user when the gripper reaches its maximum travel, alerting them to the limit position and preventing damage from excessive force.
[0090] It is understandable that in some embodiments, in addition to traditional button control, an electric control system can be added. For example, a micro motor can be installed in the first clamping structure 250 and the second clamping structure 350. The user issues commands via a touchscreen or remote control, and the motor drives the clamping component to move. This approach is particularly suitable for applications requiring frequent adjustments to the clamping state, such as outdoor shooting and live streaming, greatly improving operational efficiency and convenience. Simultaneously, the electric control system can also integrate intelligent sensing functions to automatically identify the size of external components and adjust the clamping force, further enhancing the user experience.
[0091] Further referring to Figures 10 to 14, in some embodiments, the first clamping member 251 and the first main body structure 240 are engaged in a snap-fit manner, with the button indirectly acting on the first clamping member 251 via a spring 700. For example, when the first clamping member 251 is in the retracted state, it is engaged with the first main body structure 240 and remains relatively stationary. When the button is pressed, the spring 700 compresses, pushing out the first clamping member 251, causing it to protrude from the first main body structure 240, i.e., the first clamping member 251 is in a clamping state. In the clamping state, the first clamping member 251 and the first main body structure 240 are engaged, maintaining relative stationary relative to the first main body structure 240. In subsequent operations, the user can press the first clamping member 251 to compress it back, ultimately bringing it to the retracted state. The design of the second clamping member 351 is similar and will not be described further here.
[0092] Through the above design, this application can clamp the external component from opposite sides, thereby fixing it to the external component, expanding the application scenarios and improving adaptability.
[0093] Of course, to meet more application scenarios, the clamping component can also exist in the form of a suction cup 600, that is, the first fixing seat 200 and the second fixing seat 300 are attached to the opposite sides of the external component to achieve connection with the external component. This posture is similar to clamping, and because the area of adsorption and connection is larger than that of a single fixing seat connection, the bracket 10 with this design is more stable and firm in its connection with the external component.
[0094] Referring to Figures 15 and 16, in some embodiments, the first fixing base 200 includes a suction cup 600 for adhering to the second fixing base 300, ensuring a more stable connection between the first fixing base 200 and the second fixing base 300 in the first state. In some embodiments, the suction cup 600 is used to adhere to external components to improve the adaptability of the bracket 10 of this application. In some embodiments, the second fixing base 300 includes a suction cup 600 for adhering to the first fixing base 200, or the suction cup 600 is used to adhere to external components.
[0095] Referring to Figures 18 and 19, in some embodiments, the first fixing base 200 includes a first snap-fit structure 260, and the second fixing base 300 includes a second snap-fit structure 360. The first snap-fit structure 260 is disposed facing the second snap-fit structure 360. In a first state, the first snap-fit structure 260 and the second snap-fit structure 360 cooperate to save space and make the connection between the first fixing base 200 and the second fixing base 300 more stable.
[0096] Referring to Figures 24 to 28, the specific structure of the highly adaptable support 10 is described below. In some embodiments, the highly adaptable support 10 further includes a housing 900, which can accommodate the first fixing seat 200 and the second fixing seat 300. Specifically, the housing 900 can define a receiving cavity 910. It should be noted that the housing 900 can close or open the receiving cavity 910. In some embodiments, the highly adaptable support 10 includes a cover, which can be slidably connected to the housing 900 to open and close the receiving cavity 910. In other embodiments, the highly adaptable support 10 includes a cover, which can be rotatably connected to the housing 900 to open and close the receiving cavity 910.
[0097] It should be noted that in some embodiments, both the first fixing seat 200 and the second fixing seat 300 can be housed in the receiving cavity 910. In other embodiments, the first fixing seat 200, the second fixing seat 300, and the intermediate connecting member 400 can all be housed in the receiving cavity 910. In other embodiments, the first fixing seat 200, the second fixing seat 300, the intermediate connecting member 400, and the supporting part 100 can all be housed in the receiving cavity 910. The specific housing arrangement of the box body 900 can be determined according to the actual situation. Taking the case where only the first fixing seat 200 and the second fixing seat 300 are housed in the box body 900 as an example, the box body 900 can house the first fixing seat 200 and the second fixing seat 300, which can prevent the first fixing seat 200 and the second fixing seat 300 from bumping into each other, and facilitates the overall transportation of the highly adaptable bracket 10.
[0098] Referring to Figures 24 to 26, the specific structure of the housing 900 is described below. In some embodiments, the housing 900 includes a first recess and a second recess, the structure of which can be adapted to accommodate the arrangement of the first recess. The first and second recesses are detachably connected, and the first and second recesses together define a receiving cavity 910.
[0099] It should be noted that in some embodiments, the first recessed shell can be snapped onto the second recessed shell. In other embodiments, the first recessed shell can be rotatably connected to the second recessed shell. In still other embodiments, the first recessed shell can be slidably connected to the second recessed shell. The specific configuration of the first and second recessed shells can be determined according to the actual situation. The first and second recessed shells can be detachably connected, which facilitates the opening and closing of the receiving cavity 910, effectively improving the storage efficiency of the box 900 to the fixed seat and enhancing the user experience.
[0100] Referring to Figures 24 to 26, the specific storage arrangement of the housing 900 for the fixing base is described below. In some embodiments, the first concave shell has a first opening, which communicates with the receiving cavity 910. The second concave shell has a second opening, which communicates with the receiving cavity 910. The shape and size of the second opening may be the same as or different from the first opening; an example is given where the shape and size of the first and second openings are identical.
[0101] The first opening can communicate with the second opening and together form a third opening. When the first fixing seat 200 and the second fixing seat 300 are located in the receiving cavity 910, both opposite ends of the intermediate connecting member 400 pass through the third opening. Since both ends of the intermediate connecting member 400 can pass through the third opening, when it is necessary to connect the first fixing seat 200 and the second fixing seat 300 to external components, it is only necessary to open the first and second concave shells to expose the receiving cavity 910, without disassembling the box body 900 and the intermediate connecting member 400. The operation of removing and placing the fixing seats in the box body 900 is convenient and quick.
[0102] Referring to Figure 5, the assembly connection between the box body 900 and the first fixing base 200 and the second fixing base 300 is described below. In some embodiments, the box body 900 may be provided with a first magnetic absorbing member, the first fixing base 200 may be provided with a second magnetic absorbing member, and the second fixing base 300 may be provided with a third magnetic absorbing member. The positions of the first magnetic absorbing member, the second magnetic absorbing member, and the third magnetic absorbing member can be arranged relative to each other. When the first fixing base 200 and the second fixing base 300 are located in the receiving cavity 910, the second magnetic absorbing member and the third magnetic absorbing member are both magnetically connected to the first magnetic absorbing member. In some embodiments, the first magnetic absorbing member has a first magnetic absorbing block and a second magnetic absorbing block, and the two magnetic absorbing blocks can be arranged one-to-one in the two concave shells. The first magnetic absorbing block can be magnetically connected to the second magnetic absorbing member. The second magnetic absorbing block can be magnetically connected to the third magnetic absorbing member. In other embodiments, the first magnetic absorbing member has a first magnetic absorbing block and a second magnetic absorbing block, and both magnetic absorbing blocks can be arranged in the first concave shell or the second concave shell. In other embodiments, the first fixing seat 200 can be snapped into the first concave shell, and the second fixing seat 300 can be snapped into the second concave shell. The following description will illustrate an example where both the first fixing seat 200 and the second fixing seat 300 are magnetically connected to the box body 900.
[0103] Both the first fixing seat 200 and the second fixing seat 300 are magnetically connected to the box body 900. Therefore, the separation or connection operation between the first fixing seat 200 and the second fixing seat 300 and the box body 900 is convenient and quick, and can ensure the stability of the first fixing seat 200 and the second fixing seat 300 stored in the receiving cavity 910.
[0104] In some embodiments, referring to FIG25, the housing 900 is configured to be connected to an external component. Specifically, in some embodiments, the housing 900 can be magnetically connected to the external component. In other embodiments, the housing 900 can be snap-fitted or adhesively attached to the external component. In still other embodiments, the housing 900 can also clamp-fit or thread-fit the external component, etc.
[0105] It should be noted that in some embodiments, the first fixing seat 200 can be accommodated in the receiving cavity 910, and both the box body 900 and the second fixing seat 300 can be connected to external components. In other embodiments, the second fixing seat 300 can be accommodated in the receiving cavity 910, and both the box body 900 and the first fixing seat 200 can be connected to external components. In still other embodiments, both the first fixing seat 200 and the second fixing seat 300 can be accommodated in the receiving cavity 910, and only the box body 900 is connected to external components. The specific connection configuration between the box body 900 and external components can be determined according to the actual situation.
[0106] The housing 900 can be directly connected to external components, which can ensure the stability of the assembly connection between the highly adaptable bracket 10 and the external components, and can eliminate the need to remove the first fixing seat 200 or the second fixing seat 300 from the receiving cavity 910, thus ensuring the assembly connection efficiency between the highly adaptable bracket 10 and the external components.
[0107] To ensure reliable connection between the intermediate connector 400 and the support portion 100, the first fixing seat 200, and the second fixing seat 300, in some embodiments, the highly adaptable bracket 10 includes a first connecting structure 810 and a second connecting structure 820. The first connecting structure 810 is sleeved on the end of the intermediate connector 400 and has a through hole 811. It should be noted that the connection between the first connecting structure 810 and the intermediate connector 400 can be achieved through an interference fit, or by threaded connection, adhesive connection, welding, or other connection methods to ensure a secure connection.
[0108] Referring to Figures 20 to 23, the second connecting structure 820 passes through the through hole 811 and is engaged with one of the supporting portion 100, the first fixing seat 200, or the second fixing seat 300. Specifically, when the first connecting structure 810 and the second connecting structure 820 are used only for connecting the intermediate connector 400 and the supporting portion 100, the second connecting structure 820 passes through the through hole 811 and is engaged with the supporting portion 100, thereby achieving a tight fixation between the intermediate connector 400 and the supporting portion 100. Similarly, when the first connecting structure 810 and the second connecting structure 820 are used for connecting the intermediate connector 400 and the first fixing seat 200 or the second fixing seat 300, the second connecting structure 820 passes through the through hole 811 and is engaged with the first fixing seat 200 or the second fixing seat 300, ensuring a stable connection between the intermediate connector 400 and the first fixing seat 200 or the second fixing seat 300. It is understandable that the first connecting structure 810 can be made of various materials, including but not limited to metal, plastic, or composite materials. When the first connecting structure 810 is made of metal, it can be tightly connected to the metal part inside the intermediate connector 400 through welding or other methods (i.e., the silicone layer wrapped around the outside of the metal part is removed from the end of the intermediate connector 400 used to connect the first connecting structure 810), thereby ensuring the overall strength and durability of the intermediate connector 400. It should be noted that, in order to improve the aesthetics of the highly adaptable bracket 10, after the first connecting structure 810 is connected to the intermediate connector 400, the outer surface of the first connecting structure 810 is consistent with the outer surface of the intermediate connector 400, forming a smooth transition, which not only ensures the aesthetics of the structure but also improves the overall user experience.
[0109] Specifically, the first connecting structure 810 includes a connecting sleeve fitted onto the end of the intermediate connecting member 400 and a flat portion. The flat portion can be integrally formed with the connecting sleeve, and a through hole 811 extends through the flat portion in a direction perpendicular to the axis of the intermediate connecting member 400. The second connecting structure 820 can adopt a columnar structure adapted to the through hole 811, so that the second connecting structure 820 can smoothly pass through the through hole 811. The dimension of the second connecting structure 820 along the extension direction of the through hole 811 is larger than the extension dimension of the through hole 811. Therefore, the portion of the second connecting structure 820 protruding from the through hole 811 can effectively clamp the bearing part 100, the first fixing seat 200, or the second fixing seat 300, thereby ensuring the stability and reliability of the connection. This makes the connection and disassembly of the intermediate connecting member 400 with different components more flexible, improving the convenience and flexibility of use. Users can easily separate or reconnect the intermediate connecting member 400 with other components without the need for additional tools.
[0110] The support portion 100 is provided with a first mounting hole 150 and a first snap-fit hole, wherein the first snap-fit hole extends along a direction perpendicular to the axis of the first mounting hole 150 and communicates with the first mounting hole 150. A first connecting structure 810 is sleeved on the end of the intermediate connecting member 400 and inserted into the first mounting hole 150, while a second connecting structure 820 is inserted into the first snap-fit hole and passes through the through hole 811. This design allows the support portion 100 to be firmly fixed on the intermediate connecting member 400, while facilitating assembly and disassembly.
[0111] Similarly, the first fixing base 200 is provided with a second mounting hole 270 and a second snap-fit hole, the second snap-fit hole communicating with and extending vertically from the second mounting hole 270. A first connecting structure 810 is inserted into the second mounting hole 270, and a second connecting structure 820 passes through the second snap-fit hole and is inserted into the through hole 811, ensuring a stable connection between the intermediate connector 400 and the first fixing base 200 while improving the ease of assembly or disassembly. The second fixing base 300 is provided with a third mounting hole and a third snap-fit hole, the third snap-fit hole communicating with and extending vertically from the third mounting hole. A first connecting structure 810 is inserted into the third mounting hole, and a second connecting structure 820 passes through the third snap-fit hole and is inserted into the through hole 811, ensuring a stable connection between the intermediate connector 400 and the second fixing base 300, further improving the overall structural stability and ease of operation.
[0112] Referring to Figures 20 to 23, the highly adaptable bracket 10 includes a clamping member 830, which is mounted on the support portion 100 and / or the first fixing seat 200 and / or the second fixing seat 300. Specifically, the clamping member 830 is used to clamp and fix the first connecting structure 810, ensuring that it will not shake or shift during use, thereby further enhancing the tightness and stability between the intermediate connecting member 400 and each fixing seat. In some embodiments, the clamping member 830 may be provided only on the support portion 100 to ensure a more secure connection between the intermediate connecting member 400 and the support portion 100, avoiding displacement or shaking of the support portion 100 relative to the intermediate connecting member 400 due to gravity or external vibration, which could lead to instability of the electronic device. In other embodiments, the clamping member 830 is also provided on both the first fixing seat 200 and the second fixing seat 300 to achieve multi-point fixation of the intermediate connecting member 400, further improving the vibration resistance and stability of the overall structure.
[0113] Specifically, the clamping member 830 has a first hole and a second hole, wherein the second hole extends along a direction perpendicular to the axis of the first hole and communicates with the first hole. A first connecting structure 810 is inserted into the first hole, while a second connecting structure 820 passes through the second hole and through a through hole 811. With this structure, when the first connecting structure 810 is inserted into the first hole, the second connecting structure 820 can pass through the second hole and act on the clamping member 830. For ease of description, the two side walls of the first hole arranged opposite each other along a direction perpendicular to the axis are defined as the first wall and the second wall. The first wall and the second wall can abut against the surface of the first connecting structure 810 under the action of the second connecting structure 820, increasing the friction between the first connecting structure 810 and the clamping member 830, thereby ensuring the stability of the connection. The second connecting structure 820 can be connected to the clamping member 830 using connection methods including but not limited to threaded connections, snap-fit connections, and elastic clamping, so that the clamping member 830 can tightly abut against the first connecting structure 810 under the locking action of the second connecting structure 820, preventing it from loosening or falling off during use. To further improve safety, elastic pads can be added to the first and second walls of the clamping member 830. These pads can increase friction and prevent the first connecting structure 810 from slipping out accidentally.
[0114] Referring to Figures 20 to 23, to further enhance the clamping effect of the clamping member 830 on the first connecting structure 810 and ensure that it does not loosen due to long-term use or vibration, in some embodiments, the first wall is provided with a first protrusion 831 extending toward the first connecting structure 810, and the second wall is provided with a second protrusion extending toward the first connecting structure 810. Both the first protrusion 831 and the second protrusion are adapted to abut against the surface of the first connecting structure 810, thereby applying additional pressure to the first connecting structure 810, increasing its friction with the clamping member 830, and thus ensuring a long-term stable fixing effect. In addition, the second protrusion and the first protrusion 831 are staggered along the axial direction parallel to the first hole. This staggered design can effectively disperse pressure, avoid the risk of damage caused by concentrated stress, and further enhance the clamping effect of the clamping member 830 on the first connecting structure 810, thereby enhancing the stability of the overall structure.
[0115] In some embodiments, the first protrusion 831 and the second protrusion may be configured to be elastic to adapt to different pressure changes during long-term use and maintain a stable clamping force. The first protrusion 831 and the second protrusion may be made of materials including but not limited to rubber, plastic or other highly elastic materials to ensure that the clamping member 830 can provide an effective clamping effect on the first connecting structure 810 while facilitating the installation of the first connecting structure 810.
[0116] To facilitate the separation and merging of the first fixing seat 200 and the second fixing seat 300, in some embodiments, the first fixing seat 200 is provided with a first mating member 220, and the second fixing seat 300 is provided with a second mating member 320. The first mating member 220 and the second mating member 320 are configured to be detachably connected, allowing the first fixing seat 200 and the second fixing seat 300 to be easily separated or joined. Users can quickly complete the separation or joining operation of the first fixing seat 200 and the second fixing seat 300 without using tools, improving the convenience and efficiency of use. In some embodiments, the first mating member 220 and the second mating member 320 can achieve rapid connection and release through means including but not limited to magnetic force, attraction force, or mechanical locking.
[0117] Referring to Figures 20 to 23, to ensure the feasibility of connecting the intermediate connector 400 to the first fixed base 200 and the second fixed base 300, in some embodiments, the intermediate connector 400 includes a first part, a second part, and a third part. One end of the first part is connected to the support portion 100, and the ends of the second and third parts located in the same direction are connected to the other end of the first part. Specifically, the end of the second part away from the first part is connected to the first fixed base 200, and the end of the third part away from the first part is connected to the second fixed base 300. This structural design allows the second and third parts to move away from or towards each other as the first fixed base 200 and the second fixed base 300 move. This ensures that the highly adaptable bracket 10 of this application remains stable even on irregular mounting surfaces, and the flexible adjustment of the intermediate connector 400 ensures that the device is always at the optimal viewing angle, effectively avoiding visual deviation and improving the user experience.
[0118] It should be noted that when the first fixed seat 200 and the second fixed seat 300 are separated from each other, the distance between the first fixed seat 200 and the second fixed seat 300 increases, the pressure distribution of the electronic device on the bearing part 100 is more uniform, which enhances the support force and improves the stability.
[0119] The above are merely preferred embodiments of this application and do not limit the scope of the patent application. Any equivalent structural transformations made based on the inventive concept of this application and the contents of the specification and drawings of this application, or direct / indirect applications in other related technical fields, are included within the scope of patent protection of this application.
Claims
A highly adaptable bracket suitable for detachable connection of electronic devices, characterized in that: The highly adaptable support includes: A support portion for connecting the electronic device; A fixing part is connected to the bearing part. The fixing part includes a first fixing seat and a second fixing seat. The first fixing seat is connected to the bearing part and is adapted to connect to an external component. The second fixing seat is connected to the bearing part and is adapted to connect to an external component. The highly adaptable bracket has a first state and a second state. In the first state, the first fixing seat and the second fixing seat are connected to each other, and in the second state, the first fixing seat and the second fixing seat are separated from each other. The highly adaptable support according to claim 1 is characterized in that, The highly adaptable bracket also includes an intermediate connector, which connects the load-bearing part, the first fixed seat, and the second fixed seat respectively, and is used to realize force transmission and position adjustment among the load-bearing part, the first fixed seat, and the second fixed seat. The highly adaptable support according to claim 2 is characterized in that, The intermediate connecting member includes a first connecting member and a second connecting member. Along the extending direction of the first connecting member, the first connecting member has two relatively distributed ends. One end of the first connecting member is connected to the first fixing seat, and the other end of the first connecting member is connected to the bearing portion. Along the extending direction of the second connecting member, the second connecting member has two relatively distributed ends. One end of the second connecting member is connected to the bearing portion, and the other end of the second connecting member is connected to the second fixing seat. The highly adaptable support according to claim 2 is characterized in that, The highly adaptable bracket includes an intermediate connector comprising a first part, a second part, and a third part. One end of the first part is connected to the load-bearing portion. The ends of the second part and the third part, which are in the same direction, are connected to the other end of the first part. The end of the second part away from the first part is connected to the first fixing seat. The end of the third part away from the first part is connected to the second fixing seat. The second part and the third part are configured to move away from or closer to each other as the first fixing seat and the second fixing seat move. The highly adaptable support according to claim 2 is characterized in that, The support portion is configured to slide relative to the intermediate connector along the extension direction of the intermediate connector; And / or, When the intermediate connector is in a straight state, its extension direction is the first direction, and the bearing portion is configured to rotate relative to the intermediate connector about an axis parallel to the first direction. The highly adaptable support according to claim 5 is characterized in that, The highly adaptable bracket also includes a locking part, which is connected to the support part and the intermediate connector respectively. The locking part has a locked state and an unlocked state. When the locking part is in the locked state, it restricts the movement of the support part relative to the intermediate connector. When the locking part is in the unlocked state, it releases the restriction on the support part. The highly adaptable support according to claim 1 is characterized in that, The first fixing base includes a first mating member, and the second fixing base includes a second mating member. The first mating member connects to the second mating member so that the first fixing base and the second fixing base are connected to each other. The highly adaptable support according to claim 7 is characterized in that, The first mating component includes a first magnet, and the second mating component includes a second magnet, wherein the first magnet and the second magnet have opposite magnetic properties; wherein, The first magnet is adapted to magnetically attract the second magnet; and / or, The first magnet is adapted to magnetically attract the external component; and / or, The second magnet is adapted to magnetically attract the external component. The highly adaptable support according to claim 1 is characterized in that, The first fixing base includes a first snap-fit structure, and the second fixing base includes a second snap-fit structure. The first snap-fit structure is disposed facing the second snap-fit structure, and in the first state, the first snap-fit structure and the second snap-fit structure cooperate. The highly adaptable support according to claim 1 is characterized in that, The first fixing base includes a first main body structure and a first clamping structure, the first clamping structure being movably connected to the first main body structure. The second fixing base includes a second main body structure and a second clamping structure, the second clamping structure being movably connected to the second main body structure. The highly adaptable bracket has a clamping state and a retracted state. In the clamping state, the first clamping structure protrudes from the first main body structure toward the second fixing base, and the second clamping structure protrudes from the second main body structure toward the first fixing base. Both the first clamping structure and the second clamping structure are adapted to abut against the external component so that the highly adaptable bracket clamps the external component. In the retracted state, the first clamping structure is close to the first main body structure, and the second clamping structure is close to the second main body structure so that the bracket can be separated from the external component. The highly adaptable support according to claim 10 is characterized in that, The first clamping structure includes a first clamping member and a first button. Both the first button and the first clamping member are movably connected to the first main body structure. The first button is connected to the first clamping member. The first button moves relative to the first main body structure so that the first clamping member moves away from the first main body structure. The second clamping structure includes a second clamping member and a second button. Both the second button and the second clamping member are movably connected to the second main structure. The second button is connected to the second clamping member. The second button moves relative to the second main structure so that the second clamping member moves away from the second main structure. The highly adaptable support according to claim 1 is characterized in that, The first mounting base includes a suction cup for attaching to the second mounting base, or for attaching to the external component; and / or, The second fixing base includes the suction cup, which is used to adhere to the first fixing base, or the suction cup is used to adhere to the external component. The highly adaptable support according to claim 2 is characterized in that, The highly adaptable bracket also includes a housing that defines a receiving cavity and is configured to close or open the receiving cavity, wherein the first fixing seat and the second fixing seat are both configured to be housed in the receiving cavity. The highly adaptable support according to claim 13 is characterized in that, The box body includes a first concave shell and a second concave shell, the first concave shell and the second concave shell are detachably connected, and the first concave shell and the second concave shell together define the receiving cavity. The highly adaptable support according to claim 14 is characterized in that, The first concave shell has a first opening communicating with the receiving cavity, and the second concave shell has a second opening communicating with the receiving cavity. The first opening and the second opening communicate with each other and are combined to form a third opening. When the first fixing seat and the second fixing seat are provided in the receiving cavity, the opposite ends of the intermediate connecting member are both inserted through the third opening. The highly adaptable support according to claim 13 is characterized in that, The box body is provided with a first magnetic suction member, the first fixing seat is provided with a second magnetic suction member, and the second fixing seat is provided with a third magnetic suction member. When the first fixing seat and the second fixing seat are located in the receiving cavity, the second magnetic suction member and the third magnetic suction member are both magnetically connected to the first magnetic suction member. The highly adaptable support according to claim 13 is characterized in that, The housing is configured to be attached to the external component. The highly adaptable support according to claim 2 is characterized in that, The highly adaptable bracket further includes a first connecting structure and a second connecting structure. The first connecting structure is sleeved on the end of the intermediate connector and has a through hole. The second connecting structure passes through the through hole and is engaged with the bearing portion, the first fixing seat, or the second fixing seat. The highly adaptable support according to claim 18 is characterized in that, The bearing portion is provided with a first mounting hole and a first snap-fit hole. The first snap-fit hole extends along the axis perpendicular to the first mounting hole and communicates with the first mounting hole. The first connecting structure is sleeved on the end of the intermediate connecting member and inserted into the first mounting hole. The second connecting structure is inserted into the first snap-fit hole and passes through the through hole. Alternatively, the first fixing base is provided with a second mounting hole and a second snap-fit hole, the second snap-fit hole extends along the axis perpendicular to the second mounting hole and communicates with the second mounting hole, the first connecting structure is sleeved on the end of the intermediate connecting member and inserted into the second mounting hole, and the second connecting structure is inserted into the second snap-fit hole and passes through the through hole; Alternatively, the second fixing base is provided with a third mounting hole and a third snap-fit hole. The third snap-fit hole extends along the axis perpendicular to the third mounting hole and communicates with the third mounting hole. The first connecting structure is sleeved on the end of the intermediate connecting member and inserted into the third mounting hole. The second connecting structure is inserted into the third snap-fit hole and passes through the through hole. The highly adaptable support according to claim 18 is characterized in that, The highly adaptable bracket further includes a clamping member, which is installed on the bearing portion and / or the first fixing seat and / or the second fixing seat. The clamping member has a first hole and a second hole, the second hole extending along an axis perpendicular to the first hole and communicating with the first hole. The first hole has a first wall and a second wall disposed opposite to each other along a direction perpendicular to the axis. The first connecting structure is inserted into the first hole, and the second connecting structure is inserted into the second hole and passes through the through hole. The first wall and the second wall are configured to abut against the surface of the first connecting structure under the action of the second connecting structure. The highly adaptable support according to claim 20 is characterized in that, The first wall has a first protrusion extending toward the first connecting structure, the first protrusion being adapted to abut against the surface of the first connecting structure. The second wall has a second protrusion extending toward the first connecting structure, the second protrusion being adapted to abut against the surface of the first connecting structure and arranged alternately with the first protrusion along a direction parallel to the axis of the first hole. The highly adaptable support according to claim 1 is characterized in that, The fixing part includes a magnetic attraction structure, which magnetically attracts and adsorbs the external component; or... The fixing part includes a threaded structure, which is threadedly connected to the external component; or... The fixing part includes a strap structure that is bound to the external component; or... The fixing part includes a suction cup structure, which is adsorbed onto the external component; or... The fixing part includes an adhesive structure, which is bonded to the external component; or... The fixing part includes a nested structure, and the nested structure and the external component are interference-fitted. or, The fixing part includes a snap-fit structure that snaps into the external component; or... The fixing part includes a clamping structure that clamps the external component; or... The support portion includes a magnetic attraction structure, which magnetically attracts and adsorbs the electronic device; or... The support portion includes a threaded structure, which is threadedly connected to the electronic device; or... The support portion includes a strap structure, which is used to secure the electronic device; or... The support portion includes a suction cup structure, which is attached to the electronic device; or... The support portion includes an adhesive structure, which is adhered to the electronic device; or... The support portion includes a nested structure, and the nested structure is interference-fitted with the electronic device. or, The supporting part includes a locking structure that engages with the electronic device; or... The support portion includes a clamping structure that clamps the electronic device.