Electronic device bracket

CN224433932UActive Publication Date: 2026-06-30SHENZHEN LANHE TECHNOLOGIES CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN LANHE TECHNOLOGIES CO LTD
Filing Date
2025-06-05
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing electronic device brackets have limited rotation angles when recessed for storage, or protrude and affect the thickness and functionality of the device when no recess is provided, resulting in poor support.

Method used

The design employs a linkage auxiliary component, which raises the height of the second rotating shaft to avoid interference between the rotation of the support component and the base or protective shell, thus enabling smooth rotation of the support component.

Benefits of technology

The increased rotation angle range of the bracket avoids interference between the support and the protective shell, reduces the device thickness, and maintains wireless charging efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses an electronic device bracket, including a support member and a rotating structure. The rotating structure enables the support member to rotate. The rotating structure includes: an intermediate member, with a first connecting portion and a second connecting portion respectively on opposite sides of the intermediate member; the second connecting portion includes a first sub-connecting portion and a second sub-connecting portion spaced apart; the first connecting member is rotatably connected to the first connecting portion via a first rotating shaft; the second connecting member is connected to the support member and is rotatably connected to the second connecting portion via a second rotating shaft; a linkage auxiliary member is disposed between the first sub-connecting portion and the second sub-connecting portion, and the second rotating shaft passes sequentially through the first sub-connecting portion, the linkage auxiliary member, and the second sub-connecting portion, with the linkage auxiliary member being relatively fixed in the circumferential direction of the second rotating shaft. By setting the linkage auxiliary member, rotation and transmission are achieved, and the height of the second rotating shaft can be raised by the linkage auxiliary member, avoiding interference between the support member and the base or protective shell during rotation.
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Description

Technical Field

[0001] This application relates to the field of electronic device accessories technology, and in particular to an electronic device bracket. Background Technology

[0002] Mobile phones, tablets, and other electronic devices are favored by many users due to their rich functionality and portability. In practical scenarios such as watching videos and video communication, users often want to be able to operate the electronic devices without holding them, allowing them to perform other operations while viewing the screen. In this case, a stand can be used to support the electronic device, freeing up the user's hands.

[0003] Taking phone cases as an example, a stand is typically mounted on the back panel of the phone case to support electronic devices. The stand usually needs to rotate to achieve support and storage. To prevent the stand from protruding from the phone case surface when stored, a groove is usually designed into the case to house it. However, due to this groove, after the stand has rotated to a certain angle, the edge of the groove will abut against the stand, preventing further rotation. This limited rotation angle results in a small adjustable range when adjusting the phone's support angle, leading to insufficient support for the user. Without a groove, although the stand can rotate to a larger angle, it protrudes from the phone case surface when stored, increasing the case's thickness and affecting other functions. For example, during wireless charging, if the stand protrudes from the case surface, it increases the distance between the phone and the wireless charger, slowing down or even interrupting wireless charging. Therefore, how to maximize the stand's rotation angle while incorporating a groove is a pressing issue that needs to be addressed. Utility Model Content

[0004] This application discloses an electronic device bracket, including a support member and a rotating structure. The rotating structure is used to realize the rotation of the support member, and the rotating structure includes:

[0005] The intermediate component has a first connecting portion and a second connecting portion on opposite sides, and the second connecting portion includes a first sub-connecting portion and a second sub-connecting portion that are spaced apart.

[0006] The first connector is rotatably connected to the first connecting part via a first rotating shaft;

[0007] The second connector is connected to the support member and is rotatably connected to the second connecting part via the second rotating shaft;

[0008] A linkage auxiliary component includes a linkage part and an auxiliary part. The linkage part is connected to the second rotating shaft and is relatively fixed in its circumferential direction. The first sub-connecting part and the second sub-connecting part are both connected to the second rotating shaft and are located on both sides of the linkage part, respectively. The auxiliary part extends toward the first connecting part and beyond the first sub-connecting part and the second sub-connecting part.

[0009] Compared with the prior art, this application has at least the following beneficial effects:

[0010] The electronic device bracket disclosed in this application, by setting a linkage auxiliary component, realizes the rotation of the support component and the transmission of the rotating structure itself. At the same time, the linkage auxiliary component can raise the height of the second rotating shaft, avoiding interference between the support component and the base or protective shell during rotation. When the protective shell has a groove to accommodate the support component, the rotation of the support component can drive the linkage auxiliary component to rotate, thereby raising the height of the second rotating shaft. This allows the support component to move away from the protective shell during rotation, avoiding interference between the rotation of the support component and the protective shell. Attached Figure Description

[0011] To more clearly illustrate the technical solutions in this application, the drawings used in the application will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.

[0012] Figure 1 This is a three-dimensional structural diagram of the electronic device bracket in the embodiments of this application;

[0013] Figure 2 yes Figure 1 The diagram shown is an exploded view of the support structure.

[0014] Figure 3 yes Figure 2 A partial enlarged view of the bracket shown;

[0015] Figure 4 yes Figure 1 A schematic diagram of the intermediate component in the support structure shown;

[0016] Figure 5 yes Figure 1 A schematic diagram showing the connection and separation of the second rotating shaft and the linkage auxiliary component in the bracket structure shown;

[0017] Figure 6 yes Figure 1 A schematic diagram of the intermediate component in the support structure from another angle;

[0018] Figure 7 yes Figure 1A schematic diagram of the rotating structure in the support structure shown;

[0019] Figure 8 yes Figure 7 An exploded view of the rotating structure shown;

[0020] Figure 9 yes Figure 1 A schematic diagram of the base in the support structure shown;

[0021] Figure 10 yes Figure 9 An exploded view of the base shown;

[0022] Figure 11 yes Figure 1 The diagram shows the support components being stored and stacked relative to the base in the bracket structure.

[0023] Figure 12 yes Figure 11 The cross-sectional view of the support structure shown;

[0024] Figure 13 yes Figure 12 A partially enlarged cross-sectional view of the support structure shown;

[0025] Figure 14 yes Figure 12 The diagram shows a cross-sectional view of the support structure after the support member is rotated and opened. Detailed Implementation

[0026] 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 some embodiments of this application, and not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.

[0027] In this application, the terms "upper," "inner," "outer," "middle," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. These terms are primarily for the purpose of better describing this application and its embodiments, and are not intended to limit the indicated device, element, or component to having a specific orientation, or to be constructed and operated in a specific orientation.

[0028] Furthermore, in addition to indicating location or positional relationship, some of the aforementioned terms may also have other meanings. For example, the term "above" may also be used in some cases to indicate a certain dependency or connection relationship. Those skilled in the art can understand the specific meaning of these terms in this application based on the specific circumstances.

[0029] Furthermore, the terms "provided with" and "connected" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral structure; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium, or an internal connection between two devices, components, or parts. Those skilled in the art can understand the specific meaning of these terms in this application based on the specific circumstances.

[0030] Furthermore, the terms "first," "second," etc., are primarily used to distinguish different devices, components, or parts (which may be the same or different in specific type and construction), and are not intended to indicate or imply the relative importance or quantity of the indicated devices, components, or parts. Unless otherwise stated, "a plurality of" means two or more.

[0031] Stands support electronic devices (such as mobile phones and tablets) by positioning them at a suitable angle to the user, freeing up their hands and making them highly popular. For portability, stands may be integrated into the protective case of the electronic device or designed to detachably connect to it, for example, via magnetic attachment. This allows the stand to be securely attached to the device, making it easy for users to carry and use.

[0032] However, taking phone cases as an example, stands are typically mounted on the back panel of the phone case to support electronic devices. These stands usually need to rotate to achieve support and storage. To prevent the stand from protruding from the phone case surface when stored, a groove is usually designed into the case to house it. Due to this groove, after the stand has rotated to a certain angle, the edge of the groove will abut against the stand, preventing further rotation. This limited rotation angle results in a small adjustable angle range when the user adjusts the phone's support, leading to insufficient support. Without a groove, although the stand can rotate to a larger angle, it protrudes from the phone case surface when stored, increasing the case's thickness and affecting other functions. For example, during wireless charging, if the stand protrudes, it increases the distance between the phone and the wireless charger, slowing down or even interrupting wireless charging. Therefore, how to maximize the stand's rotation angle while incorporating a groove is a pressing issue that needs to be addressed.

[0033] To address the aforementioned technical problems, this application provides an electronic device bracket. By incorporating a linkage auxiliary component, the rotation of the support component and the transmission of the rotating structure itself are achieved. Simultaneously, the linkage auxiliary component can raise the height of the second rotating shaft, preventing interference between the support component and the base or protective shell during rotation. When a groove is provided on the protective shell to house the support component, the rotation of the support component drives the linkage auxiliary component to rotate, thereby raising the height of the second rotating shaft. This allows the support component to rotate away from the protective shell, preventing interference between the support component and the protective shell.

[0034] It is understood that the electronic device holder is configured to be disposed on the surface of the electronic device to support it. For example, it can be disposed on the back of the electronic device, that is, on the surface of the electronic device opposite to the display / viewing / operation surface. The electronic device can be a mobile phone, tablet computer, e-reader, etc., and this application does not specifically limit it.

[0035] The technical solution of this application will be further described below with reference to the embodiments and accompanying drawings.

[0036] Please refer to the following: Figures 1 to 4 The electronic device bracket provided in this application embodiment includes a support member 1 and a rotating structure 2. The rotating structure 2 is used to realize the rotation of the support member 1, that is, the support member 1 can be rotated through the rotating structure 2 to support at an angle, or to be stored after rotation. The rotating structure 2 includes an intermediate member 21, and a first connecting part 211 and a second connecting part 212 are respectively provided on opposite sides of the intermediate member 21. Further, the second connecting part 212 includes two parts, namely a first sub-connecting part 212a and a second sub-connecting part 212b arranged at intervals. The first connecting member 22 is rotatably connected to the first connecting part 211 through a first rotating shaft 24, and the second connecting member 23 is connected to the support member 1 and is rotatably connected to the second connecting part 212 through a second rotating shaft 25. The linkage auxiliary component 26 includes a linkage part 26a and an auxiliary part 26b. The linkage part 26a is connected to the second rotating shaft 25 and is relatively fixed in the circumferential direction of the second rotating shaft 25, meaning that there is no relative rotation between them. When the second rotating shaft 25 rotates relative to the intermediate component 21, it will cause the linkage auxiliary component 26 to rotate relative to the intermediate component 21 as well. The first sub-connecting part 212a and the second sub-connecting part 212b are both connected to the second rotating shaft 25 and are located on both sides of the linkage part 26a, respectively. The auxiliary part 26b extends toward the first connecting part 211 and exceeds the first sub-connecting part 212a and the second sub-connecting part 212b. When the second rotating shaft 25 rotates relative to the intermediate component 21, it will cause the auxiliary part 26b to rotate as well. When it rotates to a certain angle, the auxiliary part 26b will abut against the base of the bracket, or the electronic device or electronic device accessory, and raise the height of the second rotating shaft 25 by abutting against it.

[0037] By setting up the linkage auxiliary component 26, the rotation of the support component 1 and the transmission of the rotating structure 2 itself are realized. At the same time, the linkage auxiliary component 26 can raise the height of the second rotating shaft 25, avoiding interference between the support component 1 and the base or protective shell during rotation. When the protective shell has a groove to accommodate the support component 1, the rotation of the support component 1 can drive the linkage auxiliary component 26 to rotate, thereby raising the height of the second rotating shaft 25. This allows the support component 1 to move away from the protective shell during rotation, avoiding interference between the rotation of the support component 1 and the protective shell.

[0038] In some embodiments, further refer to Figure 5 The linkage part 26a is provided with a first shaft hole 261, which is a closed circle. The inner sidewall of the first shaft hole 261 is provided with a first plane 261a, and the outer peripheral surface of the second rotating shaft 25 is provided with a second plane 25a. When the second rotating shaft 25 is inserted into the first shaft hole 261, the first plane 261a and the second plane 25a are aligned so that the linkage part 26a is relatively fixed in the circumferential direction of the second rotating shaft 25, that is, the linkage part 26a and the second rotating shaft 25 will not rotate. Figure 5 As shown, the second rotating shaft 25 is typically designed as a cylindrical structure to facilitate its rotation. To prevent rotation between the second rotating shaft 25 and the linkage part 26a, a flat surface is cut out on the outer circumference of the second rotating shaft 25, and a flat surface is also cut out on the inner sidewall of the first shaft hole 261. When the second rotating shaft 25 is inserted into the first shaft hole 261, the first flat surface 261a and the second flat surface 25a are aligned. In this case, the arrangement of the two flat surfaces does not affect the insertion of the second rotating shaft 25 into the first shaft hole 261. However, when they rotate relative to each other, the two flat surfaces provide significant resistance, preventing relative rotation and thus fixing them in place. In other embodiments, the linkage part 26a and the second rotating shaft 25 can also be designed as an integrally formed structure, i.e., a single structure manufactured through processes such as casting, injection molding, or CNC cutting.

[0039] In some embodiments, further refer to Figure 4 and Figure 6The intermediate component 21 also includes a main body 213. A first sub-connecting part 212a is provided at one end of the main body 213 and protrudes from the main body 213 in a direction away from the first connecting part 211. A second shaft hole 212c is formed on the first sub-connecting part 212a. A second sub-connecting part 212b is provided at one end of the main body 213. The first sub-connecting part 212a and the second sub-connecting part 212b are located at the same end of the main body 213. The second sub-connecting part 212b protrudes from the main body 213 in a direction away from the first connecting part 211. A third shaft hole 212d is formed on the second sub-connecting part 212b. The second rotating shaft 25 passes through the second shaft hole 212c, the first shaft hole 211 and the third shaft hole 212d in sequence. The second rotating shaft 25 can rotate within the second shaft hole 212c and the third shaft hole 212d. In other words, the rotation of the second rotating shaft 25 drives the second connecting member 23 and the support member 1 connected to the second connecting member 23 to rotate, thereby opening the support member. Since the linkage auxiliary member 26 is relatively fixed in the circumferential direction of the second rotating shaft 25, the rotation of the second rotating shaft 25 can also drive the linkage auxiliary member 26 to rotate. The rotation of the linkage auxiliary member 26 adjusts the intermediate member 21 from horizontal to inclined, thereby changing the height of the second connecting part 212 and raising the height of the second rotating shaft 25. The support member 1 can be moved away from the protective shell, avoiding interference between the rotation of the support member 1 and the protective shell.

[0040] For further details, please refer to [link / reference]. Figure 3 and Figure 6In some embodiments, the second plane 25a on the outer peripheral surface of the second rotating shaft 25 extends along the length direction of the second rotating shaft 25 to the opposite ends of the second rotating shaft 25. That is, the second plane 25a may extend to the end faces of the opposite ends of the second rotating shaft 25, or it may not extend to the end faces of the opposite ends of the second rotating shaft 25, but it must be ensured that the portion passing through the shaft hole has the second plane 25a. The first sub-connecting portion 212a is wound to form the second shaft hole 212c. One end of the first sub-connecting portion 212a is connected to the main body portion 213, while the other end is not in contact with the main body portion 213 or itself. Instead, it is spaced apart from the main body portion 213 to form a first deformation space 212e. The existence of the first deformation space 212e allows the first sub-connecting portion 212a to deform when an external force is applied to cause the second rotating shaft 25 to rotate. This causes the gap between the other end of the first sub-connecting portion 212a and the main body portion 213 to increase, i.e., the first deformation space 212e widens. The second shaft hole 212c enlarges, allowing the second rotating shaft 25 to rotate within the second shaft hole 212c. Simultaneously, due to the deformation of the first sub-connecting portion 212a, it has a tendency to return to its original position, which applies a force to the second rotating shaft 25, causing it to rotate and driving the support member 1 to rotate toward the storage position. Similarly, the second sub-connecting part 212b is wound to form the third shaft hole 212d. One end of the second sub-connecting part 212b is connected to the main body part 213, while the other end is not in contact with the main body part 213 or itself. Instead, it is spaced apart from the main body part 213 to form a second deformation space 212h. The existence of the second deformation space 212h allows the second sub-connecting part 212b to deform when an external force is applied to cause a rotational tendency between the second rotating shaft 25 and the second sub-connecting part 212b. This causes the gap between its other end and the main body part 213 to increase, i.e., the second deformation space 212h to widen. The third shaft hole 212d then enlarges, allowing the second rotating shaft 25 to rotate within the third shaft hole 212d. At the same time, since the first sub-connecting part 212a has deformed, it has a tendency to return to its original position, which will apply a force to the second rotating shaft 25 to rotate, causing the support member 1 to rotate toward the storage position.

[0041] Therefore, when the support member 1 is already in the retracted state, if the first sub-connecting part 212a and the second sub-connecting part 212b are deformed, the tendency of the two to reset will make the retracted support member 1 more stable. If the force applied to the support member 1 to open is less than a certain range, the support member 1 will not open. Specifically, by providing a third plane 212f and a fourth plane 212i on the inner surfaces of the second connecting part 212, namely the inner surfaces of the second shaft hole 212c and the third shaft hole 212d respectively, and by providing the third plane 212f near the other end of the first sub-connecting part 212a, that is, near the first deformation space 212e, and the fourth plane 212i near the other end of the second sub-connecting part 212b, that is, near the second deformation space 212h, by setting the third plane 212f and the fourth plane 212i away from the second plane 25a on the outer circumference of the second rotating shaft 25, that is, by setting the third plane 212f (fourth plane 212i) and the second plane 25a at a certain angle, the second connecting part 212 can deform through the first deformation space 212e and the second deformation space 212h when the support member 1 is in the storage position.

[0042] In some embodiments, continue reading Figure 3 and Figure 6 The first deformation space 212e extends along the insertion direction of the second rotating shaft 25 and passes through the two opposite ends of the first sub-connector 212a in the insertion direction of the second rotating shaft 25. The insertion direction of the second rotating shaft 25 is also the length direction of the first sub-connector 212a. This arrangement allows the first sub-connector 212a to deform in coordination with the rotation of the second rotating shaft 25. If the first deformation space 212e is too short, the first sub-connector 212a may not be able to deform, affecting the rotation of the second rotating shaft 25. Similarly, the second deformation space 212h is also set to extend along the insertion direction of the second rotating shaft 25 and passes through the two opposite ends of the second sub-connector 212b in the insertion direction of the second rotating shaft 25. The insertion direction of the second rotating shaft 25 is also the length direction of the second sub-connector 212b. The function of this arrangement is the same as that of the first deformation space 212e, and will not be described again here.

[0043] Furthermore, the third plane 212f also extends along the insertion direction of the second rotating shaft 25 and extends to the end faces of the first sub-connector 212a at opposite ends in the insertion direction of the second rotating shaft 25. Similarly, the fourth plane 212i extends along the insertion direction of the second rotating shaft 25 and extends to the end faces of the second sub-connector 212b at opposite ends in the insertion direction of the second rotating shaft 25. By extending the lengths of the third plane 212f and the fourth plane 212i as much as possible, it is easier to achieve the deformation of the first sub-connector 212a and the second sub-connector 212b in conjunction with the second plane 25a.

[0044] In some embodiments, further refer to Figure 3 , Figure 4 and Figure 6 The second shaft hole 212c and the third shaft hole 212d are spaced apart in the axial direction of the second rotating shaft 25, which is also the length direction of the second rotating shaft 25. The first shaft hole 261 is located between the second shaft hole 212c and the third shaft hole 212d. By setting the linkage auxiliary member 26 between the first sub-connecting part 212a and the second sub-connecting part 212b, it is easier to change the height of the second connecting part 212 through the linkage auxiliary member 26, and the second connecting part 212 is subjected to more balanced forces. The second connecting part 212 is less prone to breakage and deformation under force, which can effectively improve the service life of the second connecting part 212. Furthermore, the lengths of the second shaft hole 212c and the third shaft hole 212d can be set to be equal to further balance the forces on the second connecting part 212. At the same time, the linkage auxiliary member 26 can more easily change the state of the second connecting part 212, and the rotation of the support member 1 is smoother and does not jam.

[0045] In some embodiments, further refer to Figure 7 and Figure 8 One end of the second rotating shaft 25 away from the second sub-connecting part 212b protrudes out of the second shaft hole 212c, and the other end of the second rotating shaft 25 away from the first sub-connecting part 212a protrudes out of the third shaft hole 212d. That is, after the second rotating shaft 25 is inserted into the second shaft hole 212c, the first shaft hole 261, and the third shaft hole 212d in sequence, both ends of the second rotating shaft 25 are exposed. The second connecting member 23 includes a first shaft cap 23b and a first fixing part 23a, and there are two second connecting members 23. The two first shaft caps 23b of the two second connecting members 23 are respectively sleeved on the two exposed ends of the second rotating shaft 25, and after being sleeved, they are fixed relative to the second rotating shaft 25 in its circumferential direction. That is, the two first shaft caps 23b and the second rotating shaft 25 will not rotate. At the same time, the two first fixing parts 23a are fixedly connected to the support member 1, such as by riveting or welding. By fixing the support member 1, the second connector 23 and the second rotating shaft 25 relatively, the support member 1 can rotate while driving the linkage auxiliary member 26 to move and raising the height of the second rotating shaft 25, thus solving the problem of interference between the support member 1 and the protective shell during the rotation process.

[0046] In some embodiments, see Figure 5 , Figure 13 and Figure 14The auxiliary part 26b includes an end face away from the linkage part 26a and side faces on both sides of the end face. The end face is curved. Since the end face contacts and abuts against the base 3 during the rotation of the support member 1 to raise the height of the second rotating shaft 25, the end face is curved. When the end face abuts against the base 3, the support member 1 can continue to rotate using the curved surface as a fulcrum, ensuring smooth rotation and preventing the support member 1 from ceasing to rotate due to contact with the base 3. Furthermore, the two side faces are flat and are located on opposite sides of the second rotating shaft 25. Figure 13 As can be seen, when the support component 1 is stored, the two planes cooperate with the support component 1 and the base 3 respectively, minimizing the overall thickness of the bracket. From the insertion direction of the second rotating shaft 25, the auxiliary linkage component 26 has a racetrack-like shape. The end face does not interfere with the rotation of the support component 1 when it plays its corresponding role, while the two sides reduce the thickness. The overall structure and shape design are more reasonable.

[0047] In some embodiments, see Figure 1 , Figure 9 and Figure 10 The electronic device bracket also includes a base 3, which is used to connect to the electronic device or its accessories. Taking an electronic device accessory as an example, the base 3 can be fixedly connected to the protective shell, such as by riveting or gluing, to fix the electronic device bracket to the protective shell; or the base 3 can be rotatably connected to the protective shell. By rotating the base 3 and the protective shell, the position of the support member 1 on the protective shell is adjusted to achieve support in different directions. The first connecting member 22 is connected to the base 3. The side of the base 3 facing the support member 1 also has an abutment portion 32a. When the support member 1 rotates relative to the base 3 to a preset angle, the auxiliary portion 26b abuts against the abutment portion 32a, thereby raising the height of the second rotating shaft 25. (Reference) Figure 13 and Figure 14 It can be seen that when support member 1 is retracted and closed, that is... Figure 13 As shown, the second rotating shaft 25 is basically flush with the first rotating shaft 24 and at the same height; when the support 1 rotates a certain angle relative to the base 3, as... Figure 14As shown, the linkage 26a rotates with the second rotating shaft 25, changing from rotating parallel to the base 3 to tilting relative to the base 3, and abuts against the abutment 32a. This raises the height of the second rotating shaft 25. As can be seen from the figure, the second rotating shaft 25 and the first rotating shaft 24 are no longer at the same height; the height of the second rotating shaft 25 is higher than that of the first rotating shaft 24. This effectively raises the position of the support member 1, effectively preventing interference between the support member 1 and the base 3 during rotation. Compared to the embodiment without the abutment 32a, this embodiment makes it easier to raise the height of the second rotating shaft 25 and to raise it to a more optimal height, completely avoiding interference between the support member 1 and the base 3.

[0048] In some embodiments, see Figure 9 and Figure 10 The base 3 includes a base body 31 and a base reinforcement 32 disposed on the base body 31. A notch 31a is formed on the base body 31, and the base reinforcement 32 is disposed at the notch 31a. The abutment portion 32a is a protrusion protruding from the base reinforcement 32. When the support member 1 rotates, the linkage auxiliary member 26 will abut and rub against the abutment portion 32a. Therefore, the abutment portion 32a needs to have a certain strength and hardness to ensure that the support member 1 will not lose its height due to wear or deformation and fail to function during thousands or even tens of thousands of rotations. Therefore, by setting the base reinforcement 32, the base reinforcement 32 can be made of, for example, high-strength steel to ensure that the abutment portion 32a can be used tens of thousands of times. Since the base body 31 does not require high strength, it can be made of lightweight and relatively inexpensive materials such as aluminum alloy. On the one hand, this reduces the overall weight, making the electronic device bracket more portable, and on the other hand, it reduces the overall manufacturing cost.

[0049] For further information, please refer to [link / reference]. Figure 10 The two ends of the base reinforcement 32 are respectively connected to the base body 31. The connection methods include, but are not limited to, riveting, welding, and bonding. Both ends of the base reinforcement 32 are connected to the side of the base body 31 away from the support member 1, that is, to the lower surface of the base body 31. The protrusion (i.e., the abutment part 32a) is provided on the surface of the base reinforcement 32 facing the support member 1, that is, on the upper surface of the base reinforcement 32. This arrangement ensures that the base reinforcement 32 is lower than the base body 31, and the height difference between the two creates a certain accommodating space. When the support member 1 is stored, a portion of the rotating structure 2 can be accommodated within this accommodating space, thereby reducing the overall thickness of the electronic device bracket to a certain extent. Simultaneously, an abutment part 32b can be provided on the base reinforcement 32, such as... Figure 10As shown in the figure, the clearance part 32b is a notch provided on the base reinforcement 32. By providing the clearance part 32b, when the support member 1 rotates relative to the base 3 to a preset angle, a part of the support member 1 is located in the clearance part 32b. That is to say, during the rotation of the support member 1, it can avoid interference by cooperating with the linkage auxiliary member 26 and the abutment part 32a to move away from the base 3, and it can also avoid interference by removing the part of the base reinforcement 32 that would interfere with the rotation of the support member 1 to form the clearance part 32b. With the support of the dual structure, there will be no interference between the support member 1 and the base 3, the support member 1 opens more smoothly, and the opening angle can also be increased accordingly.

[0050] In some embodiments, further refer to Figure 8 A shaft hole is formed on the first connecting part 211. The first rotating shaft 24 passes through the shaft hole and is rotatably connected to the first connecting part 211, with both ends of the first rotating shaft 24 protruding outside the shaft hole. The first connecting member 22 includes a second shaft cap 22b and a second fixing part 22a. There are two first connecting members 22. The two second shaft caps 22b of the two first connecting members 22 are respectively sleeved on both ends of the first rotating shaft 24 and are fixed relative to the first rotating shaft 24 in its circumferential direction. That is, there is no rotation between the second shaft caps 22b and the first rotating shaft 24. At the same time, the two second fixing parts 22a are respectively connected to both ends of the base body 31 with the notch, so that a part of the rotating structure 2 can be located in the accommodating space formed by the base reinforcement 32 and the base body 31. This makes the overall structure more compact and reduces the overall thickness of the bracket.

[0051] In some embodiments, see Figure 1 , Figures 11-14 A first receiving portion 11 is provided on the side of the support member 1 facing the base 3, and a second receiving portion 33 is provided on the side of the base 3 facing the support member 1. When the support member 1 is stored and stacked on the base 3, as... Figure 12 and Figure 13 As shown, the first receiving part 11 and the second receiving part 33 are aligned and together form the receiving space 4, in which the rotating structure 2 is housed. As can be seen from the figure, by housing the rotating structure 2 in the receiving space 4, the thickness of the support member 1, the rotating structure 2, and the base 3 stacked together is only the sum of the thicknesses of the support member 1 and the base 3, effectively reducing the overall thickness of the bracket and making the bracket easier to carry, install, and use.

[0052] In some embodiments, see Figure 3 and Figure 6The first connecting part 211 is wound to form a fourth shaft hole 211a. One end of the first connecting part 211 is connected to the main body part 213, and the other end is not in contact with the main body part 213 or itself. Instead, it is spaced apart from the main body part 213 to form a third deformation space 211b. The existence of the third deformation space 211b allows the first connecting part 211 to deform when the first rotating shaft 24 rotates with the first connecting part 211, so that the gap between its other end and the main body part 213 increases, i.e., the third deformation space 211b widens. Since the first connecting part 211 has deformed, it has a tendency to reset itself and will apply a force to the intermediate part 21 to make the intermediate part 21 return from the tilted state to the horizontal state. Therefore, when the support member 1 changes from the supported state to the retracted state, the first connecting part 211 will deform. At this time, the tendency of the first connecting part 211 to return to its original position will cause the intermediate part 21 to change from an inclined state to a horizontal state. After the support member 1 returns to the retracted state, the intermediate part 21 also becomes horizontal. The intermediate part 21 will not cause the support member 1 to tilt, and the support member 1 is more flat in the retracted state. Specifically, by setting a fifth plane 211c on the inner surface of the first connecting part 211, that is, the inner side of the fourth shaft hole 211a, and setting the fifth plane 211c close to the other end of the first connecting part 211, that is, close to the third deformation space 211b, and setting a sixth plane 24a on the outer peripheral surface of the first rotating shaft 24, the misalignment of the fifth plane 211c and the sixth plane 24a allows the first connecting part 211 to deform through the third deformation space 211b when the support member 1 rotates from the supported position to the retracted position.

[0053] The above provides a detailed description of an electronic device bracket disclosed in the embodiments of this application. This document uses specific examples to illustrate the principles and implementation methods of this application. The description of the above embodiments is only for the purpose of helping to understand an electronic device bracket and its core ideas in this application. At the same time, for those skilled in the art, there will be changes in the specific implementation methods and application scope based on the ideas of this application. Therefore, the content of this specification should not be construed as a limitation of this application.

Claims

1. An electronic device support, characterized by, include: A support member and a rotating structure, wherein the rotating structure is used to realize the rotation of the support member, and the rotating structure includes: The intermediate component has a first connecting portion and a second connecting portion on opposite sides, and the second connecting portion includes a first sub-connecting portion and a second sub-connecting portion that are spaced apart. The first connector is rotatably connected to the first connecting part via a first rotating shaft; The second connector is connected to the support member and is rotatably connected to the second connecting part via the second rotating shaft; A linkage auxiliary component includes a linkage part and an auxiliary part. The linkage part is connected to the second rotating shaft and is relatively fixed in its circumferential direction. The first sub-connecting part and the second sub-connecting part are both connected to the second rotating shaft and are located on both sides of the linkage part, respectively. The auxiliary part extends toward the first connecting part and beyond the first sub-connecting part and the second sub-connecting part.

2. The electronic device holder of claim 1, wherein, The linkage part is provided with a first shaft hole, the inner sidewall of the first shaft hole is provided with a first plane, and the outer peripheral surface of the second rotating shaft is provided with a second plane. When the second rotating shaft is inserted into the first shaft hole, the first plane and the second plane are arranged facing each other so that the linkage part is relatively fixed in the circumferential direction of the second rotating shaft. Alternatively, the linkage part and the second rotating shaft are integrally formed.

3. The electronic device holder of claim 1, wherein, The linkage part is provided with a first shaft hole. The intermediate part also includes a main body part. The first sub-connecting part is provided at one end of the main body part and protrudes from the main body part in a direction away from the first connecting part, forming a second shaft hole. The second sub-connecting part is provided at one end of the main body part and protrudes from the main body part in a direction away from the first connecting part, forming a third shaft hole. The first sub-connecting part and the second sub-connecting part are located at the same end of the main body part. The second rotating shaft passes through the second shaft hole, the first shaft hole and the third shaft hole in sequence, and the second rotating shaft can rotate within the second shaft hole and the third shaft hole.

4. The electronic device holder of claim 3, wherein, The second rotating shaft has a second plane on its outer circumferential surface, and the second plane extends along the length of the second rotating shaft to the opposite ends of the second rotating shaft; The first sub-connecting part is wound to form the second shaft hole. One end of the first sub-connecting part is connected to the main body part, and the other end is spaced apart from the main body part to form a first deformation space. The second sub-connecting part is wound to form the third shaft hole. One end of the second sub-connecting part is connected to the main body part, and the other end is spaced apart from the main body part to form a second deformation space.

5. The electronic device holder of claim 4, wherein, The inner surface of the first sub-connecting part is provided with a third plane. The third plane is located near the other end of the first sub-connecting part. When the third plane is offset from the second plane, the first sub-connecting part can deform through the first deformation space. The inner surface of the second sub-connector is provided with a fourth plane. The fourth plane is located near the other end of the second sub-connector. When the fourth plane is offset from the second plane, the second sub-connector can deform through the second deformation space.

6. The electronic device holder of claim 3, wherein, The second shaft hole and the third shaft hole are spaced apart along the length of the second rotating shaft, and the first shaft hole is located between the second shaft hole and the third shaft hole; And / or, the second shaft hole and the third shaft hole are spaced apart along the length of the second rotating shaft, and the length of the second shaft hole is equal to the length of the third shaft hole.

7. The electronic device holder of claim 3, wherein, The second rotating shaft has one end protruding from the second shaft hole away from the second sub-connecting part, and the other end protruding from the third shaft hole away from the first sub-connecting part. The second connecting member includes two parts, each of which includes a first shaft cap and a first fixing part. The first shaft caps of the two second connecting members are respectively sleeved on both ends of the second rotating shaft and are fixed relative to the second rotating shaft in its circumferential direction. The first fixing parts of the two second connecting members are fixedly connected to the support member.

8. The electronic device holder of claim 1, wherein, The auxiliary part includes an end face away from the linkage part and side faces on both sides of the end face; The end face is an arc surface, and / or both sides are planes, and the two sides are located on opposite sides of the second rotating shaft.

9. The electronic device bracket according to any one of claims 1-8, characterized in that, The electronic device bracket also includes a base for connecting to an electronic device or electronic device accessories. The first connector is connected to the base. The base has an abutment portion on the side facing the support member. When the support member rotates relative to the base to a preset angle, the auxiliary portion abuts against the abutment portion to raise the height of the second rotating shaft.

10. The electronic device holder of claim 9, wherein, The base includes a base body and a base reinforcement member disposed on the base body. A notch is formed on the base body, and the base reinforcement member is disposed at the notch. The abutting part is a protrusion protruding from the base reinforcement member.

11. The electronic device holder of claim 10, wherein, Both ends of the base reinforcement are connected to the base body and are both connected to the side of the base body away from the support. The protrusion is provided on the surface of the base reinforcement facing the support. The base reinforcement is also provided with a clearance portion. When the support rotates relative to the base to a preset angle, a part of the support is located in the clearance portion.

12. The electronic device holder of claim 10, wherein, The first connector includes two parts, each of which includes a second shaft cap and a second fixing part. The second shaft caps of the two first connectors are respectively sleeved on both ends of the first rotating shaft and are fixed relative to the first rotating shaft in its circumferential direction. The two second fixing parts are respectively connected to both ends of the base body that forms the notch.

13. The electronic device holder of claim 9, wherein, The support member has a first receiving portion on the side facing the base, and the base has a second receiving portion on the side facing the support member. When the support member is stored and stacked on the base, the first receiving portion and the second receiving portion are aligned and together form a receiving space, and the rotating structure is stored in the receiving space.

14. The electronic device holder according to any one of claims 3-7, wherein, The first connecting part is wound to form a fourth shaft hole. One end of the first connecting part is connected to the main body, and the other end is spaced apart from the main body to form a third deformation space. A fifth plane is provided on the inner surface of the first connecting part. The fifth plane is provided near the other end of the first connecting part. A sixth plane is provided on the outer peripheral surface of the first rotating shaft. The fifth plane and the sixth plane cooperate to allow the first connecting part to deform through the third deformation space.