WO2020187027A1

WO2020187027A1 - Terminal device

Info

Publication number: WO2020187027A1
Application number: PCT/CN2020/077744
Authority: WO
Inventors: 林协源
Original assignee: 维沃移动通信有限公司
Priority date: 2019-03-20
Filing date: 2020-03-04
Publication date: 2020-09-24
Also published as: CN109862248B; CN109862248A

Abstract

Disclosed is a terminal device. The terminal device comprises a shell, a camera and a drive mechanism, wherein the shell is provided with an opening and a guide rail; the drive mechanism drives the camera to enter and exit the opening; the drive mechanism comprises a first magnetic member, a second magnetic member and a hooking part; one end of the hooking part is rotatably connected to the camera, and the other end thereof comprises a first hook; the first hook is in sliding fit with the guide rail; the guide rail is provided with a hooking section; the first magnetic member is arranged in the shell, and the second magnetic member is arranged at the camera; the first magnetic member applies a magnetic repulsive force to the second magnetic member; in the process of the camera being pressed by an external force and moving into the shell through the opening, the first hook slides into the hooking section and is connected to the hooking section in a hooked manner; and in the process of the camera being pressed by an external force and moving out of the shell through the opening, the first hook slides out of the hooking section, and the magnetic repulsive force drives the camera to move out of the shell.

Description

Terminal Equipment

Cross references to related applications

This application claims the priority of Chinese Patent Application No. 201910214264.X filed in China on March 20, 2019, the entire content of which is incorporated herein by reference.

Technical field

The present disclosure relates to the technical field of communication equipment, and in particular to a terminal device.

Background technique

In related technologies, the screen occupancy ratio of the terminal device is increasing, and the larger screen occupancy ratio enables the appearance performance and display performance of the terminal device to be greatly improved, thereby improving the user experience. In order to achieve an increase in the screen ratio, more and more terminal devices use cameras that can be raised and lowered. In the working process of the terminal device of this structure, when shooting is required, the camera is moved outside the housing of the terminal device under the drive of the driving mechanism, and then shooting can be realized; when the shooting is completed, the camera is driven by the driving mechanism Move down into the housing of the terminal device, and then can realize the hiding of the camera. The camera with this structure does not occupy the board space of the terminal device, and thus can increase the screen occupying ratio.

In the actual operation process, the movement of the camera is realized by the driving of the driving mechanism. The drive mechanism usually includes a drive motor and a reducer, and the cost of these devices is high, which often leads to an increase in the production cost of the terminal device.

Summary of the invention

The present disclosure discloses a terminal device to solve the problem of high production cost caused by the use of a drive motor and a reducer in the terminal device in the related art.

In order to solve the above problems, the present disclosure adopts the following technical solutions:

A terminal device includes a housing, a camera, and a drive mechanism arranged in the housing. The housing has an inner cavity and an opening communicating with the inner cavity. The drive mechanism is connected to the camera and drives The camera enters and exits the opening, the driving mechanism includes a first magnetic member, a second magnetic member, and a hooking part, a guide rail is provided in the housing, and one end of the hooking part is rotatably connected to the On the camera, the other end of the hook portion includes a first hook, the first hook is slidingly fitted with the guide rail, the guide rail has a hook section, and the first magnetic member is arranged in the housing , The second magnetic member is disposed on the camera and moves with the camera, the first magnetic member and the second magnetic member have opposite magnetic properties and apply a magnetic repulsive force to the second magnetic member. When the camera is pressed by an external force and moved into the housing through the opening, the first hook slides into the hook section and is hooked and matched with the hook section; the camera is subjected to external force During the process of pressing to move out of the housing through the opening, the first hook slides out of the hooking section, and the magnetic repulsive force drives the camera to move out of the housing.

The technical solution adopted by the present disclosure can achieve the following beneficial effects:

The terminal device disclosed in the present disclosure improves the structure of the terminal device in the related technology, so that the user can control the camera expansion and contraction only by pressing. When the camera needs to work, the user can manually press the camera so that the movement of the camera drives the suspension The first hook of the connecting part is detached from the hooking section of the guide rail. At this time, the camera is only subjected to magnetic repulsion. Driven by the magnetic repulsion, the camera can move out of the housing through the opening; when the camera needs to be hidden, the user can manually Press the camera, so that the movement of the camera drives the first hook of the hook part to slide into the hook section, so as to achieve the hook fit. Under the pull of the hook section, the camera can overcome the magnetic repulsion force and remain in the cavity of the housing . It can be seen that the terminal device disclosed in the present disclosure does not require expensive components such as a drive motor and a reducer, and therefore can reduce production costs.

Description of the drawings

The drawings described here are used to provide a further understanding of the present disclosure and constitute a part of the present disclosure. The exemplary embodiments of the present disclosure and their descriptions are used to explain the present disclosure, and do not constitute an improper limitation of the present disclosure. In the attached picture:

FIG. 1 is a schematic diagram of a partial structure of a terminal device disclosed in an embodiment of the disclosure;

2 and 3 are respectively structural schematic diagrams of the camera and the first magnetic member in different viewing angles after being assembled according to the embodiments of the disclosure;

4 is a schematic diagram of the structure of the guide block disclosed in the embodiment of the disclosure;

Figure 5 is a bottom view of the guide block disclosed in the embodiment of the disclosure;

6 is a schematic diagram of the structure of the hook portion disclosed in the embodiment of the disclosure;

Figures 7-10 are schematic diagrams of the telescopic process of the camera in the terminal device disclosed in the embodiments of the disclosure.

Description of reference signs:

100-shell, 110-inner cavity, 120-guide block, 121-guide rail, 1211-hanging section, 1211a-first sub-slot, 1211b-second sub-slot, 1212-slide into groove, 1213-slide Out the groove, 130-screw, 140-slide,

200-camera, 210-cantilever, 211-chute, 212-connection hole,

300-drive mechanism, 310-first magnetic member, 320-second magnetic member, 330-hanging part, 331-first hook, 332-second hook.

detailed description

In order to make the objectives, technical solutions, and advantages of the present disclosure clearer, the technical solutions of the present disclosure will be described clearly and completely in conjunction with specific embodiments of the present disclosure and the corresponding drawings. Obviously, the described embodiments are only a part of the embodiments of the present disclosure, rather than all the embodiments. Based on the embodiments in the present disclosure, all other embodiments obtained by those of ordinary skill in the art without creative work shall fall within the protection scope of the present disclosure.

The technical solutions disclosed in each embodiment of the present disclosure will be described in detail below with reference to the accompanying drawings.

Please refer to FIG. 1 to FIG. 10, an embodiment of the present disclosure discloses a terminal device. The disclosed terminal device includes a housing 100, a camera 200, and a driving mechanism 300.

The housing 100 is a peripheral basic component of the terminal device, and the housing 100 can provide an installation foundation for other components of the terminal device. In the embodiment of the present disclosure, the driving mechanism 300 and the camera 200 are both installed in the housing 100. The housing 100 has an inner cavity 110 and an opening, and the opening communicates with the inner cavity 110 to realize the position switch of the camera 200 outside the inner cavity 110 and the housing 100. Generally, the housing 100 includes a frame, and the opening may be provided on the frame. In the embodiment of the present disclosure, a guide rail 121 is provided in the housing 100.

The camera 200 is an image acquisition component of the terminal device. The camera 200 is movably disposed on the housing 100, and the camera 200 can switch between different positions by moving relative to the housing 100. In the embodiment of the present disclosure, the driving mechanism 300 is connected to the camera 200 and drives the camera 200 in and out of the opening. Specifically, the driving mechanism 300 can drive the camera 200 from the inner cavity 110 of the housing 100 through the opening to move outside the housing 100; of course, the driving mechanism 300 can also drive the camera 200 to pass through the opening from outside the housing 100. The hole moves to the inner cavity 110 of the housing 100.

The driving mechanism 300 includes a first magnetic member 310, a second magnetic member 320, and a hooking portion 330. One end of the hooking portion 330 is rotatably connected to the camera 200, and can be rotated relative to the camera 200 to adapt to the second described later. The position of a hook 331 changes during the sliding process. Specifically, one end of the hooking portion 330 may be provided with a rotating shaft. Correspondingly, the camera 200 may be provided with a connecting hole, and the rotating shaft can rotate with the connecting hole; of course, it may also be that one end of the hooking portion 330 may be provided with a connecting hole. Correspondingly, the camera 200 may be provided with a rotating shaft, and the rotating shaft is rotationally matched with the connecting hole. The embodiment of the present disclosure does not limit the specific rotation matching structure between the hooking portion 330 and the camera 200.

The other end of the hooking portion 330 includes a first hook 331, and the first hook 331 is slidably engaged with the guide rail 121. In the actual working process, the first hook 331 can slide relative to the guide rail 121 with the movement of the camera 200.

In the embodiment of the present disclosure, the guide rail 121 has a hooking section 1211. The hooking section 1211 is used for hooking and cooperating with the first hook 331. When the camera 200 is moved to the inner cavity 110 of the housing 100, the hooking section 1211 Hook and cooperate with the first hook 331 to hold the camera 200 in the cavity 110.

The first magnetic member 310 is arranged in the housing 100. Generally, the first magnetic member 310 is fixed in the housing 100. For example, the first magnetic member 310 may be fixed in the housing 100 by means of bonding; for another example, the first magnetic member 310 may be fixed in the housing 100 by means of screw connection or clip fixing.

The second magnetic member 320 is disposed on the camera 200 and moves with the camera 200. During the movement of the camera 200, the second magnetic member 320 follows the movement. Of course, in the embodiment of the present disclosure, the second magnetic member 320 moves under force. During the process, the camera 200 will move together. Specifically, the second magnetic member 320 may be fixed to the camera 200. Specifically, the second magnetic member 320 may be fixedly connected to the camera 200 by means of adhesive fixation, clamping fixation, or fixation by a screw connection.

In the embodiment of the present disclosure, the magnetic properties of the first magnetic member 310 and the second magnetic member 320 are opposite, and the first magnetic member 310 applies a magnetic repulsion force to the second magnetic member 320.

When the camera 200 is pressed by an external force to move into the housing 100 through the opening, the first hook 331 slides into the hook section 1211 and is hooked and matched with the hook section 1211, and finally the camera 200 can be held in the housing. In the inner cavity of 100, in this process, the user usually manually presses the camera 200 to overcome the magnetic repulsion, so that the camera 200 is moved. The hook section 1211 cooperates with the first hook 331, so that the camera 200 can overcome the magnetic repulsion and finally hold In the lumen 110.

When the camera 200 is pressed by an external force to move out of the housing 100 through the opening, the first hook 331 slides out from the hook section 1211, and the hook section 1211 is evacuated by the pulling force exerted on the camera 200 by the first hook 331. In this case, the magnetic repulsive force drives the camera 200 to move out of the housing 100 through the opening, so that the camera 200 can perform shooting work.

It can be seen from the above working process that the terminal device disclosed in the embodiment of the present disclosure improves the structure of the terminal device in the related art, so that the user can control the telescopic camera 200 only by manually pressing, and when the camera 200 needs to be extended to work The user can manually press the camera 200, so that the camera 200 moves into the terminal device to drive the first hook 331 of the hooking portion 330 to disengage from the hooking section 1211 of the guide rail 121. After the user releases his hand, the camera 200 is only subjected to magnetic repulsion. Driven by the magnetic repulsion, the camera 200 can move out of the housing 100 through the opening; when the camera 200 needs to be hidden, the user can manually press the camera 200 to make the camera The movement of 200 drives the first hook 331 of the hooking portion 330 to slide into the hooking section 1211, so as to achieve the hooking fit. Under the pulling of the hooking section 1211, the camera 200 can overcome the magnetic repulsive force and remain in the housing 100. In the cavity 110, it can be seen that the terminal device disclosed in the embodiment of the present disclosure does not need expensive components such as a drive motor and a reducer, and therefore can reduce production costs.

At the same time, in the process of driving the camera 200 to move outside the housing 100, the first magnetic member 310 provided on the housing 100 exerts a magnetic repulsion force on the second magnetic member 320 provided on the camera 200, and the magnetic repulsion force is The non-contact force can therefore simplify the structure of the driving mechanism 300 and reduce the problem of unstable equipment life due to mechanical assembly.

As described above, when the camera 200 moves outside the housing 100, the first magnetic member 310 and the second magnetic member 320 are magnetically opposite, and the first magnetic member 310 can apply a magnetic repulsive force to the second magnetic member 320. The second magnetic member 320 is fixed on the camera 200 and moves with the camera 200. Therefore, the distance between the second magnetic member 320 and the first magnetic member 310 will change at least during the movement of the camera 200. Obviously, as As the distance changes, the magnitude of the magnetic repulsion received by the camera 200 will also change. During the movement of the camera 200 outside the housing 100, in order to ensure that the driving of the camera 200 is more stable, the first magnetic member 310 may extend along the axial direction of the opening. In this case, the first magnetic member 310 may have a certain length in the extending direction of the camera 200, so as to alleviate the insufficient magnetic repulsion drive caused by the second magnetic member 320 being far away from the first magnetic member 310 when the camera 200 is extended The problem.

In a more optional solution, when the camera 200 is moved into the housing 100, the second magnetic member 320 and the first magnetic member 310 can be at least partially overlapped. This assembly structure can reduce the overall driving mechanism 300 The size of the camera 200 in the telescopic direction is beneficial to reduce the hollowed-out area of the circuit board in the terminal device (for example, the main board of the terminal device), so that the circuit board of the terminal device has a larger area to integrate electronic functional devices. It should be noted that, that the second magnetic member 320 and the first magnetic member 310 are at least partially overlapped means that the second magnetic member 320 and the first magnetic member 310 are at least partially overlapped. Normally, the two overlapping parts can be at least partially overlapped. Do not touch to avoid friction. Specifically, when the camera 200 is retracted into the housing 100, the second magnetic member 320 and the first magnetic member 310 are at least partially overlapped in the thickness direction of the terminal device, and the thickness direction refers to perpendicular to The orientation of the terminal's display screen.

In order to make the movement of the camera 200 more stable, the housing 100 may be provided with a sliding rail 140, the camera 200 may be provided with a sliding groove 211, the sliding rail 140 and the sliding groove 211 are slidingly fitted in the moving direction of the camera 200, and the sliding rail 140 and the sliding groove The sliding fit of the 211 can play a better guiding role and make the movement stability of the camera 200 higher. Of course, the slide rail 140 can also be provided on the camera 200, and correspondingly, the slide groove 211 is provided on the housing 100.

As described above, when the camera 200 is moved into the housing 100, the second magnetic member 320 and the first magnetic member 310 may at least partially overlap. In this case, the magnetic repulsion will produce a certain lateral force, which is not conducive to the movement of the camera 200. Based on this, in an alternative solution, the sliding rail 140 may be a T-shaped sliding rail, and the sliding groove 211 may be a T-shaped sliding groove. . The camera 200 and the housing 100 cooperate with the T-shaped groove and the T-shaped slide rail to better limit the position in each side direction, and prevent the camera 200 from jamming laterally and affecting the extension problem.

Generally, the camera 200 has a certain thickness, and the housing 100 has an empty housing structure. In order to facilitate the assembly of the hooking portion 330, in a more optional solution, a guide block 120 may be provided in the housing 100, and a guide rail 121 can be provided on the guide block 120, the guide block 120 has a certain thickness, so that the size difference between the guide rail 121 and the camera 200 in the thickness direction of the terminal device can be made smaller, which is beneficial to the rotation of the hook portion 330 and the camera 200 The connection can also further facilitate the cooperation between the first hook 331 and the guide rail 121. The guide block 120 is usually fixed in the inner cavity 110 of the housing 100, for example, the guide block 120 is fixed in the inner cavity 110 of the housing 100 by screws 130.

The guide block 120 is usually arranged on one side of the camera 200. A cantilever 210 can be fixed on one side edge of the camera 200. The cantilever 210 and the guide rail 121 are arranged on the same side of the camera 200. One end of the hook portion 330 is rotatably connected to the cantilever. On 210, the slide rail 140 or the slide groove 211 may be provided on the cantilever 210. The cantilever 210 can extend to one side of the camera 200, which is more conducive to connecting with the guide rail 121 arranged on the same side of the camera 200 through the hooking portion 330.

In a more optional solution, the cantilever 210 may be provided with a connecting hole 212, the end of the hook 330 rotatably connected to the camera 200 is a second hook 332, and the first hook 331 and the second hook 332 may be hook parts respectively. At both ends of 330, the second hook 332 is hooked with the connecting hole 212, and the second hook 332 is rotatably fitted with the connecting hole 212. In other words, the two ends of the hook portion 330 are matched with the camera 200 and the guide rail 121 through the first hook 331 and the second hook 332, respectively. The above structure has the advantages of simple assembly and easy disassembly and assembly.

As mentioned above, the housing 100 usually includes a frame, and the opening can be provided on the frame. When the camera 200 is moved outside the housing 100, the cantilever 210 can be matched with the frame limit, thereby preventing the camera 200 from overextending. The problem. In this case, the cantilever 210 not only has the function of optimizing the assembly, but also has the function of determining the final extended position of the camera 200.

In the embodiment of the present disclosure, the guide rail 121 can have various structures. The guide rail 121 can be a strip-shaped protrusion with a guiding function, and the strip-shaped protrusion has a section that can serve as a hooking section 1211. In order to achieve a more stable fit with the hooking portion 330, in an optional solution, the guide rail 121 may be a guide groove, and the first hook 331 extends into the guide groove and slidably fits with the guide groove.

The guide rail 121 includes a hook section 1211 and a guide section. The hook section 1211 is hooked up to the first hook 331. The guide section can guide the first hook 331 to slide in or out of the hook section 1211. Of course, the camera 200 moves to In the process outside the housing 100, the first hook 331 can slide out from the hook section 1211 and enter the guide section; when the camera 200 is moved into the housing 100, the first hook 331 can move from the guide section Slide into the hook section 1211.

Generally, the function of the guide segment can be realized by the same groove, or by two grooves (the sliding-in groove 1212 and the sliding-out groove 1213 as described below). Please refer to FIGS. 1 to 10 again. In an alternative solution, the guide rail 121 may include a sliding-in groove 1212, a sliding-out groove 1213, and the above-mentioned hook section 1211, and the first sliding into the groove 1212 The end is communicated with the first end of the sliding-out groove 1213, and the second end of the sliding-in groove 1212 and the second end of the sliding-out groove 1213 are respectively connected to two ends of the hook section 1211.

7-10, in the process of moving the camera 200 to the outside of the housing 100, the first hook 331 slides from the hook section 1211 to the slide groove 1213, and from the slide groove 1213 to Sliding into the groove section where the groove 1212 is located, the first hook 331 slides from the sliding groove 1212 into the hook section 1211 when the camera 200 moves into the housing 100. The sliding-in groove 1212 and the sliding-out groove 1213 can respectively guide the first hook 331, which is more conducive to the sliding fit of the first hook 331 with the guide rail 121 following the movement of the camera 200.

The hooking section 1211 is used to hook and cooperate with the first hook 331. The hooking section 1211 may have various structures. Specifically, the hooking section 1211 may be a bending groove section bent toward the extension direction of the camera 200. The hook section 1211 may include a first sub-slot 1211a and a second sub-slot 1211b, and the second sub-slot 1211b is in communication with the first sub-slot 1211a. The first sub-slot 1211a communicates with the second end of the sliding-in groove 1212, and the second sub-slot 1211b communicates with the second end of the sliding-out groove 1213. The hook section 1211 of the above structure facilitates the engagement with the sliding-in groove 1212 and the sliding-out groove 1213.

Under the premise that the guide rail 121 is a guide groove, the notches of the guide rail 121 may be located in the same plane. Under this premise, the depth of the first end of the sliding groove 1213 may be smaller than the first end of the sliding groove 1212 That is, the distance between the bottom surface of the first end of the sliding-out groove 1213 and the notch is smaller than the distance between the bottom surface of the first end of the sliding-in groove 1212 and the notch. In this case, the bottom surface of the first end sliding out of the groove 1213 and the bottom surface of the first end sliding into the groove 1212 will form a step. When the camera 200 moves into the housing 100, when the first hook When 331 slides to the connection between the first end of the slide-out groove 1213 and the first end of the slide-in groove 1212, due to the existence of the step, the first hook 331 will slide more accurately to the slide-in recess under the block of the step. In the groove 1212, it does not slide in and out of the groove 1213. It can be seen that the above-mentioned structure facilitates the first hook 331 to slide more accurately during the retracting process of the camera 200, which can achieve foolproofness.

It should be noted that in this article, the notch refers to the notch of the guide groove. The bottom surface refers to the inner surface of each part of the guide groove opposite to the notch.

In a more optional solution, the depth of the end of the second sub-slot 1211b connected to the first sub-slot 1211a may be greater than the depth of the end of the first sub-slot 1211a connected to the second sub-slot 1211b, that is, In other words, in the connecting end of the first sub-slot 1211a and the second sub-slot 1211b, the distance between the bottom of the end of the first sub-slot 1211a and the slot is relatively small. In this case, the first sub-slot 1211a and the second sub-slot 1211a The bottom surface of the end connected to the groove 1211b will form a step. When the camera 200 moves outside the housing 100, the first hook 331 slides from the second sub-slot 1211b into the groove 1213 without It will slide into the sliding groove 1212 to ensure the accuracy of the sliding direction of the first hook 331, which can further realize foolproofness.

Normally, the distance between the bottom surface of each section of the sliding groove 1212 and the notch is equal, and the depth of the first end of the sliding groove 1213 is less than the depth of the first end of the sliding groove 1212, in order to Sliding more smoothly, in the direction of the first end of the sliding-out groove 1213, the depth of the second sub-groove 1211b and the sliding-out groove 1213 may gradually decrease, as shown in the shaded part in FIG. 4.

Of course, it is also possible that the distance between the bottom surface of each section of the sliding groove 1213 and the slot opening is equal, and the distance between the bottom surface of the sliding groove 1212 and the first sub-groove 1211a is equal. The distance between the notches is gradually reduced, that is, the bottom surface of the sliding groove 1212 and the first sub-groove 1211a is gradually raised, so that the depth of the end of the second sub-groove 1211b connected to the first sub-groove 1211a can be made , Greater than the depth of the end of the first sub-slot 1211a connected to the second sub-slot 1211b.

The terminal devices disclosed in the embodiments of the present disclosure may be mobile phones, tablet computers, e-book readers, game consoles, wearable devices (such as smart watches) and other devices. The embodiments of the present disclosure do not limit the specific types of terminal devices.

The above embodiments of the present disclosure focus on the differences between the various embodiments. As long as the different optimization features between the various embodiments are not contradictory, they can be combined to form a better embodiment. Considering the conciseness of the text, here is No longer.

The foregoing descriptions are merely embodiments of the present disclosure, and are not used to limit the present disclosure. For those skilled in the art, the present disclosure can have various modifications and changes. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present disclosure should be included in the scope of the claims of the present disclosure.

Claims

A terminal device includes a housing, a camera, and a drive mechanism arranged in the housing. The housing has an inner cavity and an opening communicating with the inner cavity. The drive mechanism is connected to the camera and drives The camera enters and exits the opening, the driving mechanism includes a first magnetic member, a second magnetic member, and a hooking part, a guide rail is provided in the housing, and one end of the hooking part is rotatably connected to the On the camera, the other end of the hook portion includes a first hook, the first hook is slidingly fitted with the guide rail, the guide rail has a hook section, and the first magnetic member is arranged in the housing , The second magnetic member is disposed on the camera and moves with the camera, the first magnetic member and the second magnetic member have opposite magnetic properties and apply a magnetic repulsive force to the second magnetic member. When the camera is pressed by an external force and moved into the housing through the opening, the first hook slides into the hook section and is hooked and matched with the hook section; the camera is subjected to external force During the process of pressing to move out of the housing through the opening, the first hook slides out of the hooking section, and the magnetic repulsive force drives the camera to move out of the housing.
The terminal device according to claim 1, wherein the first magnetic member extends along the axial direction of the opening.
3. The terminal device according to claim 2, wherein, in a state where the camera is moved into the housing, the second magnetic member and the first magnetic member are at least partially overlapped.
The terminal device according to claim 1 or 2 or 3, wherein one of the housing and the camera is provided with a slide rail, and the other is provided with a slide groove, the slide rail and the slide groove Sliding fit in the moving direction of the camera.
The terminal device according to claim 4, wherein the sliding rail is a T-shaped sliding rail, and the sliding groove is a T-shaped sliding groove.
The terminal device according to claim 4, wherein a guide block is provided in the housing, the guide rail is provided on the guide block, the guide block is provided on one side of the camera, and the camera A cantilever is fixed on one side edge, the cantilever and the guide rail are arranged on the same side of the camera, one end of the hook is rotatably connected to the cantilever, and the slide rail or the slide groove is provided On the cantilever.
The terminal device according to claim 6, wherein the housing includes a frame, the opening is opened in the frame, and when the camera moves out of the housing, the cantilever is The frame limit coordination.
The terminal device according to claim 6, wherein the cantilever is provided with a connecting hole, and the end of the hook that is rotatably connected to the camera is a second hook, the first hook and the second hook They are the two ends of the hooking portion respectively, the second hook is hooked with the connecting hole, and the second hook is rotatably matched with the connecting hole.
The terminal device according to claim 1, wherein the guide rail includes a sliding-in groove, a sliding-out groove, and the hooking section, and a first end of the sliding-in groove is connected to the sliding-out groove The first end of the sliding groove is connected to the second end of the sliding groove and the second end of the sliding groove is respectively connected to the two ends of the hook section, and the camera moves to the housing During the internal process, the first hook slides into the hook section from the slide-in groove; during the process of moving the camera out of the housing, the first hook moves from the hook The connecting section slides into the slide-out groove and slides from the slide-out groove into the slide-in groove.
The terminal device according to claim 9, wherein the hooking section is a bending groove section bent toward the extension direction of the camera; the hooking section includes a first sub-slot and the first sub-slot. The second sub-slot communicated with the sub-slot, the first sub-slot communicates with the second end of the slide-in groove, and the second sub-slot communicates with the second end of the slide-out groove.
The terminal device according to claim 10, wherein the notches of the guide rail are located in the same plane, and the depth of the first end of the sliding-out groove is smaller than the depth of the first end of the sliding-in groove.
The terminal device according to claim 11, wherein the depth of the end of the second sub-slot connected to the first sub-slot is greater than that of the first sub-slot connected to the second sub-slot The depth of the end.
The terminal device according to claim 12, wherein, in a direction toward the first end of the sliding-out groove, the depths of the second sub-groove and the sliding-out groove gradually decrease.