CN113163040B

CN113163040B - Electronic device

Info

Publication number: CN113163040B
Application number: CN202110551091.8A
Authority: CN
Inventors: 张稳; 白嘉楠
Original assignee: Vivo Mobile Communication Co Ltd
Current assignee: Vivo Mobile Communication Co Ltd
Priority date: 2021-05-20
Filing date: 2021-05-20
Publication date: 2023-03-14
Anticipated expiration: 2041-05-20
Also published as: CN113163040A

Abstract

The application discloses electronic equipment relates to the communication technology field, and it includes: a first housing; the second shell is connected with the first shell in a sliding manner; the flexible display screen is switched between an unfolded state and a folded state along with the relative sliding of the first shell and the second shell; the camera module is arranged in the first shell and comprises a camera and a driving mechanism, and the driving mechanism is connected with the camera; a first member disposed within the second housing; under the condition that the flexible display screen is in a folded state, the first component limits the rotation of the camera; in the process of switching the flexible display screen from the folded state to the unfolded state, the first component and the camera are relatively far away; and under the condition that the flexible display screen is in an unfolded state, the driving mechanism drives the camera to rotate. This scheme can solve present electronic equipment and can't realize the problem of better anti-shake effect because of space restriction.

Description

Electronic device

Technical Field

The application belongs to the technical field of communication, and particularly relates to an electronic device.

Background

With the rapid development of the electronic device industry and the increasing performance requirements of consumers on electronic devices, the anti-shake performance of electronic devices is more and more important for improving the core competitiveness of electronic devices. At present, electronic equipment mostly adopts technologies such as electronic anti-shake, optics anti-shake and cloud platform anti-shake to realize the anti-shake, and these anti-shake technologies homoenergetic can solve the fuzzy problem of shooing that the in-process caused because of the shake to a certain extent, and wherein, cloud platform anti-shake is equipped with the favor with its outstanding anti-shake effect.

The cloud platform anti-shake technology mainly drives the camera to move in the opposite direction of the shake direction through the driving mechanism, so that the shake of the camera is counteracted, and finally anti-shake is achieved. Therefore, the motion space of the camera has a crucial influence on the anti-shake effect. However, since the internal space of the electronic device is limited, the motion space of the camera is insufficient, so that the anti-shake effect of the electronic device is still not desirable.

Disclosure of Invention

The embodiment of the application aims to provide electronic equipment, and the problem that the existing electronic equipment cannot achieve a better anti-shaking effect due to space limitation can be solved.

In order to solve the technical problem, the present application is implemented as follows:

an embodiment of the present application provides an electronic device, including:

a first housing;

the second shell is connected with the first shell in a sliding mode;

the flexible display screen is connected with the first shell, the second shell and the flexible display screen, and the flexible display screen is switched between an unfolded state and a folded state along with the relative sliding of the first shell and the second shell;

the camera module is arranged in the first shell and comprises a camera and a driving mechanism, and the driving mechanism is connected with the camera;

a first component disposed within the second housing;

under the condition that the flexible display screen is in the folded state, the first component limits the rotation of the camera; in the process that the flexible display screen is switched from the folded state to the unfolded state, the first component and the camera are relatively far away; and under the condition that the flexible display screen is in the unfolded state, the driving mechanism drives the camera to rotate.

In the embodiment of the application, the flexible display screen can be switched between the unfolding state and the folding state along with the relative sliding of the first shell and the second shell, the flexible display screen is switched from the folding state to the unfolding state, the first component and the camera are relatively far away, the flexible display screen is in the unfolding state, because the distance between the first component and the camera is far enough, the first component no longer limits the rotation of the camera, enough space is provided around the camera at the moment, so that the camera rotates, therefore, the driving mechanism can drive the camera to rotate with a larger amplitude, and therefore, the anti-shaking effect of the electronic equipment is improved.

Drawings

Fig. 1 to fig. 2 are schematic structural diagrams of an electronic device disclosed in an embodiment of the present application at different angles when a flexible display screen is in an unfolded state;

fig. 3 to 4 are schematic structural diagrams of the electronic device disclosed in the embodiment of the present application at different angles when the flexible display screen is in a folded state;

FIG. 5 is an exploded view of an electronic device disclosed in an embodiment of the present application;

fig. 6 is a cross-sectional view of an electronic device disclosed in an embodiment of the present application when the flexible display screen is in an unfolded state;

FIG. 7 is an enlarged view of a portion of FIG. 6;

fig. 8 to 10 are schematic diagrams of partial structures of an electronic device disclosed in an embodiment of the present application at different angles;

fig. 11 is an exploded view of a part of the structure of an electronic device disclosed in an embodiment of the present application.

Description of the reference numerals:

100-a first housing;

200-a second housing;

300-a flexible display screen;

400-camera module, 410-camera, 420-driving mechanism, 421-first driving source, 422-second driving source, 423-first rotating piece, 424-second rotating piece, 425-first rotating shaft, 426-second rotating shaft, 427-spherical piece, 428-driving belt, 429-first gear, 431-second gear, 440-decorative ring and 450-bracket;

500-first part, 510-receiving groove, 520-main board, 530-main board support;

600-a gyroscope;

700-subplate.

Detailed Description

The technical solutions in the embodiments of the present application will be described clearly and completely with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some, but not all, of the embodiments of the present application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The terms first, second and the like in the description and in the claims of the present application are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It should be understood that the data so used may be interchanged under appropriate circumstances such that embodiments of the application may be implemented in sequences other than those illustrated or described herein. In addition, "and/or" in the specification and claims means at least one of connected objects, a character "/" generally means that a preceding and succeeding related objects are in an "or" relationship.

The electronic device provided by the embodiment of the present application is described in detail below with reference to the accompanying drawings through specific embodiments and application scenarios thereof.

Referring to fig. 1 to 11, an embodiment of the present application discloses an electronic device, which includes a first housing 100, a second housing 200, a flexible display screen 300, a camera module 400, and a first component 500.

The first casing 100 and the second casing 200 are basic members of the electronic device, and can provide a mounting base for other components of the electronic device. The second housing 200 is slidably connected to the first housing 100, that is, the second housing 200 and the first housing 100 can move relatively.

The first segment of the flexible display screen 300 is connected to the first casing 100, and optionally, the first segment of the flexible display screen 300 and the first casing 100 may be connected by bonding or the like, which is not particularly limited in this embodiment of the application. The second section of the flexible display 300 is connected to the second housing 200, and the flexible display 300 is switched between the unfolded state and the folded state along with the relative sliding of the first housing 100 and the second housing 200. In other words, when the first and

second housings

100 and 200 slide relative to each other, the flexible display 300 is pulled by at least one of the first and

second housings

100 and 200, thereby switching between the unfolded state and the folded state.

The camera module 400 is disposed in the first housing 100, the camera module 400 includes a camera 410 and a driving mechanism 420, the driving mechanism 420 is connected to the camera 410, and the driving mechanism 420 can drive the camera 410 to rotate. When the camera 410 shakes, the driving mechanism 420 may drive the camera 410 to rotate in a direction opposite to the shaking direction, thereby achieving anti-shake.

The first component 500 is disposed in the second housing 200, and the first component 500 may be a component originally disposed in the electronic device to implement a predetermined function, and optionally, the first component 500 may be used to mount a battery, a circuit board, or the like. When the first housing 100 and the second housing 200 slide relative to each other, the distance between the first member 500 and the camera module 400 changes. Alternatively, the first housing 100 may move relative to the second housing 200, the second housing 200 may be fixed, the position of the camera module 400 is not changed, and the first component 500 may be far away from or close to the camera module 400; alternatively, the second housing 200 may move relative to the first housing 100, the first housing 100 may be fixed, the position of the first component 500 is not changed, and the camera module 400 may be far away from or close to the first component 500. The two embodiments can reduce the weight of the moving parts, thereby improving the reliability of the electronic device.

Under the condition that the flexible display screen 300 is in the folded state, the first component 500 limits the rotation of the camera 410, that is, at this time, the first component 500 is closer to the camera 410, and the first component and the camera can be in direct contact, or a certain gap exists between the first component and the camera, and at this time, the camera 410 cannot rotate, or the rotation angle is smaller; in the process of switching the flexible display screen 300 from the folded state to the unfolded state, the first component 500 and the camera 410 are relatively far away; under the condition that the flexible display screen 300 is in the unfolded state, the driving mechanism 420 drives the camera 410 to rotate, at this time, because the distance between the first component 500 and the camera 410 is far enough, the first component 500 does not limit the rotation of the camera 410 any more, and there is enough space around the camera 410 to facilitate the rotation of the camera 410, so that the driving mechanism 420 can drive the camera 410 to rotate in a larger amplitude, thereby improving the anti-shake effect of the electronic device; in the process of switching the flexible display screen 300 from the unfolded state to the folded state, the first component 500 and the camera 410 are relatively close to each other.

After adopting above-mentioned structure, if need realize the anti-shake, perhaps need carry out the anti-shake to the great condition of shake range, then can make first casing 100 and second casing 200 keep away from relatively to remove the restriction of first part 500 to camera 410, make camera 410 can rotate, perhaps take place rotation by a larger margin, thereby obtain better anti-shake effect. On the contrary, if the shake of the camera 410 is small, even no shake exists, or the camera 410 does not need to work, the first casing 100 and the second casing 200 can be relatively close to each other, so as to reduce the thickness of the electronic device, and facilitate the user to carry the electronic device; meanwhile, the first part 500 can limit the rotation of the camera 410 in this case, so that the problems of high noise, easy damage and the like caused by shaking of the camera 410 are solved.

Optionally, the first component 500 includes a main board 520 and a main board bracket 530, and the main board 520 is disposed on the main board bracket 530, and the two may be stacked together. At this time, the rotation of the camera 410 can be limited by the main board 520 and the main board bracket 530 together, so that the limiting effect on the camera 410 is improved. The camera 410 can be electrically connected with the main board 520, but since the main board 520 needs to move relative to the camera 410, the electrical connection structure between the two is complicated and is easily damaged. Therefore, further, the electronic device further includes a sub-board 700, and the camera 410 is electrically connected to the sub-board 700. The sub plate 700 may be disposed on the first housing 100, and thus the sub plate 700 may be fixed with respect to the camera 410, such that the electrical connection between the camera 410 and the sub plate 700 is easier to achieve, thereby simplifying the electrical connection structure of the camera 410 and improving the electrical connection reliability of the camera 410. In addition, the driving mechanism 420 may also be electrically connected to the sub-plate 700, thereby further facilitating control of the driving mechanism 420.

The first part 500 can limit the rotation of the camera 410 through its side, in other embodiments, the first part 500 is provided with a receiving groove 510, the receiving groove 510 is provided with an opening for the camera 410 to go in and out, and the camera 410 can enter the receiving groove 510 through the opening of the receiving groove 510 in the process that the camera 410 gradually approaches the first part 500; during the process that the camera 410 is gradually moved away from the first member 500, the camera 410 may move out of the receiving groove 510 through the opening of the receiving groove 510. Under the condition that the flexible display screen 300 is in the folded state, the camera 410 is matched with the accommodating groove 510, so that the rotation of the camera 410 is limited; in the case where the flexible display 300 is in the unfolded state, the camera 410 is located outside the receiving groove 510, so that the restriction of the rotation of the camera 410 is released. Since the receiving groove 510 has a certain depth, when the camera head 410 is engaged with the receiving groove 510, the receiving groove 510 can limit the rotation of the camera head 410 in at least two directions, thereby improving the effect of limiting the rotation of the camera head 410.

In an alternative embodiment, when the flexible display screen 300 is in the folded state, the driving mechanism 420 may drive the camera 410 to rotate around the first axis, and the maximum rotation angle of the camera 410 around the first axis is the first angle; under the condition that the flexible display screen 300 is in the unfolded state, the driving mechanism 420 can also drive the camera 410 to rotate around the first axis, and at this time, the maximum rotation angle of the camera 410 around the first axis is a second angle, and the second angle is larger than the first angle. That is to say, no matter what state the flexible display screen 300 is, the driving mechanism 420 can drive the camera 410 to rotate, so as to achieve anti-shake, but when the flexible display screen 300 is in the unfolded state, the maximum rotation angle of the camera 410 is greater than that when the flexible display screen 300 is in the folded state, the maximum rotation angle of the camera 410 is greater. This embodiment enables the camera 410 to realize more times of anti-shake, thereby satisfying the anti-shake requirement of the user in any state.

In another alternative embodiment, the camera 410 is fixed relative to the first component 500 when the flexible display 300 is in the folded state, that is, the camera 410 cannot rotate relative to the first casing 100 in this state, and thus the anti-shake function cannot be achieved. This embodiment makes the flexible display screen 300 in the folded state, and the camera 410 will hardly sway, thereby avoiding the camera 410 from swaying to cause problems such as large noise and easy damage.

In the embodiment of the present application, when the first casing 100 and the second casing 200 move relatively, the flexible display screen 300 deforms accordingly, and in order to prevent the flexible display screen 300 from being wrinkled, a winding shaft (not shown in the figure) may be disposed at a first edge of the first casing 100, a first section of the flexible display screen 300 is wound around the winding shaft and is in sliding fit with the first casing 100, where the first edge may be an edge of the first casing 100 departing from the second casing 200. The winding shaft may support the flexible display 300, thereby preventing the flexible display 300 from being wrinkled. The camera 410 may be disposed at a position of the first casing 100 far from the winding shaft, or may be disposed at a position of the first casing 100 near the winding shaft, and in order to fully utilize the space around the winding shaft, the camera 410 may be disposed at the first edge, thereby improving the space utilization of the electronic apparatus.

The direction that camera 410 rotated for first casing 100 can set up in a flexible way, and optionally, camera 410 can only rotate for first casing 100 in a direction, and camera 410 can only realize the anti-shake in single orientation this moment, and the anti-shake effect is relatively poor. In view of this, when the flexible display 300 is in the unfolded state, the driving mechanism 420 drives the camera 410 to rotate around a first axis and a second axis, and the first axis is perpendicular to the second axis. Because the camera 410 can rotate around the first axis and the second axis, the camera 410 can realize anti-shake in more directions, so that the anti-shake effect of the electronic device is better. Also, when the first axis and the second axis are perpendicular, the camera 410 more easily realizes a compound motion by rotation about the first axis and the second axis, thereby coping with shaking of the camera 410 in a plurality of directions.

In order to realize the rotation of the camera 410 around the first axis and the second axis respectively, the same power source can be adopted to cooperate with the transmission mechanism, so that the camera 410 rotates around different axes, and in such a way, a relatively complex transmission mechanism is required to be adopted, so that the power output by the power source is finally converted into the driving forces in different directions. Therefore, in order to simplify the driving mechanism 420, the driving mechanism 420 may optionally include a first driving source 421 and a second driving source 422, and optionally, the first driving source 421 and the second driving source 422 may each be a motor or other components capable of outputting power. The first driving source 421 and the second driving source 422 are both connected to the camera 410, the first driving source 421 drives the camera 410 to rotate around the first axis, and the second driving source 422 drives the camera 410 to rotate around the second axis. So configured, the movement of the camera 410 in different directions is realized by different driving sources, so there is no need to provide a complicated transmission mechanism to realize the change of the power direction, and thus this embodiment can simplify the driving mechanism 420. Alternatively, the first driving source 421 and the second driving source 422 may be disposed at the bottom of the camera 410, and the first driving source 421 and the second driving source 422 may output a telescopic driving force, so as to drive the camera 410 to rotate.

In a further embodiment, the driving mechanism 420 further includes a first rotating member 423, a second rotating member 424, a first rotating shaft 425 and a second rotating shaft 426, the first rotating member 423 and the second rotating member 424 are both rotatably connected to the first casing 100, one end of the first rotating shaft 425 is connected to the second rotating shaft 426, the other end of the first rotating shaft 425 is connected to the camera 410, the first rotating member 423 is sleeved outside the first rotating shaft 425, and the second rotating member 424 is sleeved outside the second rotating shaft 426. The rotation axis of the first rotating member 423 intersects or is out of plane with the first rotating shaft 425, and the rotation axis of the second rotating member 424 intersects or is out of plane with the second rotating shaft 426. Optionally, the axial centerline of the first rotating shaft 425 intersects the axial centerline of the second rotating shaft 426, and further, the axial centerline of the first rotating shaft 425 is perpendicular to the axial centerline of the second rotating shaft 426. The first driving source 421 drives the camera 410 to rotate around the axis of the second rotating shaft 426 through the first rotating shaft 425, specifically, the first driving source 421 can drive the first rotating member 423 to rotate, and since the first rotating member 423 is sleeved outside the first rotating shaft 425, the first rotating member 423 can apply a lifting force or a downward force to the first rotating shaft 425, so that the first rotating shaft 425 drives the second rotating shaft 426 to rotate relative to the second rotating member 424, so as to drive the camera 410 to rotate. The second driving source 422 drives the camera 410 to rotate around the axis of the first rotating shaft 425 through the second rotating shaft 426, specifically, the second driving source 422 may drive the second rotating member 424 to rotate, and since the second rotating member 424 is sleeved outside the second rotating shaft 426, the second rotating member 424 may apply a lifting force or a downward force to the second rotating shaft 426, so that the second rotating shaft 426 drives the first rotating shaft 425 to rotate relative to the first rotating member 423, so as to drive the camera 410 to rotate. Compared with the mode that the first driving source 421 and the second driving source 422 are both arranged at the bottom of the camera 410, the driving mechanism 420 can be arranged side by side with the camera 410, that is, the driving mechanism 420 is opposite to and connected with the side surface of the camera 410, so that the driving mechanism 420 occupies less space in the thickness direction of the electronic device, and the thickness of the electronic device is reduced.

The first rotating shaft 425 and the second rotating shaft 426 may be cylindrical structures, and one end of the first rotating shaft and one end of the second rotating shaft may be directly connected. In other embodiments, the driving mechanism 420 further includes a ball member 427, one end of the first rotating shaft 425 is connected to the second rotating shaft 426 through the ball member 427, and the ball member 427 is located between the first rotating member 423 and the second rotating member 424. The spherical member 427 is protruded with respect to the first rotating shaft 425 and the second rotating shaft 426, so the size of the spherical member 427 can be larger than the size of the first rotating shaft 425 and the second rotating shaft 426, the intersection point of the axial center line of the first rotating shaft 425 and the axial center line of the second rotating shaft 426 coincides with the sphere center of the spherical member 427, at this time, the connecting area of the first rotating shaft 425 and the spherical member 427 and the connecting area of the second rotating shaft 426 and the spherical member 427 are both larger, thereby improving the connecting strength of the first rotating shaft 425 and the second rotating shaft 426 and further prolonging the service life of the driving mechanism 420.

The first driving source 421 has a first output shaft, and the position relationship between the first output shaft and the first axis is selected in many ways, alternatively, the first output shaft may be perpendicular to the first axis, or the first output shaft may form a non-zero included angle with the first axis; the second driving source 422 has a second output shaft, and the position relationship between the second output shaft and the second axis is selected, alternatively, the second output shaft can be perpendicular to the second axis, or the second output shaft can form a non-zero included angle with the second axis. In other embodiments, the first output shaft may be parallel to the first axis, so that the direction of the driving force does not need to be changed, thereby facilitating the structural design of the driving mechanism 420; similarly, the second output shaft may be parallel to the second axis, thereby further reducing the difficulty of the structural design of the driving mechanism 420.

The first driving source 421 may directly transmit the driving force to the camera 410, but such an arrangement may cause the first driving source 421 to be too close to the camera 410, thereby limiting the rotational range of the camera 410. To solve this problem, the driving mechanism 420 may further include a transmission belt 428, and the first driving source 421 drives the camera 410 to rotate through the transmission belt 428. At this time, a first transmission gear may be disposed on a first output shaft of the first driving source 421, a first gear 429 may be disposed in the transmission belt 428, the transmission belt 428 is engaged with the first transmission gear and the first gear 429, the first transmission gear drives the transmission belt 428 to move, and the transmission belt 428 drives the first gear 429 to rotate, so as to transmit the driving force to the camera 410. In this embodiment, the first driving source 421 may be spaced apart from the camera 410 by a large distance, thereby expanding a rotation range of the camera 410.

In order to improve the transmission efficiency, the driving mechanism 420 may further include a second gear 431, and a second output shaft of the second driving source 422 may be provided with a second gear 431, which is engaged with the second gear 431, so that the camera 410 is driven to rotate by the second gear 431. In addition, in order to improve the aesthetic property of the camera module 400, the camera module 400 may further include a decorative ring 440, and the decorative ring 440 surrounds the camera 410. Further alternatively, the camera module 400 may further include a bracket 450, the first driving source 421 and the second driving source 422 may be disposed on the bracket 450, and the first rotating member 423 and the second rotating member 424 may be rotatably disposed on the bracket 450, where the bracket 450 may facilitate the installation of the first driving source 421, the second driving source 422, the first rotating member 423, and the second rotating member 424.

Alternatively, the first driving source 421 and the second driving source 422 may be used only for driving the camera 410 to rotate, or both of them may perform other functions on the premise of driving the camera 410 to rotate. Alternatively, at least one of the first driving source 421 and the second driving source 422 is a vibration motor, which can implement a vibration function of the electronic device, thereby reducing the number of vibration motors to be additionally provided even without additionally providing a vibration motor. Therefore, the embodiment can reduce the number of parts contained in the electronic equipment, thereby facilitating the layout of the parts in the electronic equipment and reducing the weight and the cost of the electronic equipment.

Further, the electronic device further includes a gyroscope 600, and under the condition that the flexible display screen 300 is in the folded state, the gyroscope 600 may monitor the center of gravity of the electronic device, so as to facilitate control over the electronic device. Further, the camera 410 has a light inlet end, the gyroscope 600 may be disposed on a side of the camera 410 away from the light inlet end, and the gyroscope 600 may be electrically connected to the sub-board 700. Under the condition that flexible display screen 300 is in the expansion state, camera 410 can drive gyroscope 600 and rotate, therefore gyroscope 600 can monitor camera module 400's center, and monitoring data can transmit to subplate 700 to be convenient for subplate 700 control camera 410's state, and then improve the anti-shake effect. In this embodiment, the gyroscope 600 is disposed on the camera 410, and further more monitoring items are executed by the gyroscope 600, so that the number of parts in the electronic device is reduced, thereby facilitating the layout of the parts in the electronic device and reducing the weight and cost of the electronic device.

The electronic device disclosed in the embodiment of the present application may be an electronic device such as a smart phone, a tablet computer, an electronic book reader, a wearable device (e.g., a smart watch), and an electronic game machine, and the kind of the electronic device is not particularly limited in the embodiment of the present application.

While the present embodiments have been described with reference to the accompanying drawings, it is to be understood that the invention is not limited to the precise embodiments described above, which are meant to be illustrative and not restrictive, and that various changes may be made therein by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. An electronic device, comprising:

a first housing (100);

a second housing (200), the second housing (200) being slidably connected to the first housing (100);

a flexible display screen (300), wherein a first section of the flexible display screen (300) is connected with the first shell (100), a second section of the flexible display screen (300) is connected with the second shell (200), and the flexible display screen (300) is switched between an unfolded state and a folded state along with the relative sliding of the first shell (100) and the second shell (200);

the camera module (400), the camera module (400) is arranged in the first shell (100), the camera module (400) comprises a camera (410) and a driving mechanism (420), and the driving mechanism (420) is connected with the camera (410);

a first component (500), the first component (500) disposed within the second housing (200);

the first component (500) limits the rotation of the camera (410) with the flexible display (300) in the collapsed state; during the process of switching the flexible display screen (300) from the folded state to the unfolded state, the first component (500) and the camera (410) are relatively far away; under the condition that the flexible display screen (300) is in the unfolded state, the driving mechanism (420) drives the camera (410) to rotate.

2. The electronic device of claim 1, wherein the first component (500) comprises a main board (520) and a main board support (530), wherein the main board (520) is disposed on the main board support (530), wherein the electronic device further comprises a sub board (700), and wherein the camera (410) is electrically connected to the sub board (700).

3. The electronic device of claim 1, wherein the first part (500) is provided with a receiving groove (510), and the receiving groove (510) is provided with an opening for the camera (410) to enter and exit;

the camera (410) is engaged with the receiving groove (510) with the flexible display (300) in the collapsed state; the camera (410) is located outside the receiving groove (510) when the flexible display (300) is in the unfolded state.

4. The electronic device of claim 1, wherein with the flexible display screen (300) in the collapsed state, the driving mechanism (420) drives the camera (410) to rotate about a first axis, and a maximum rotation angle of the camera (410) about the first axis is a first angle; under the condition that the flexible display screen (300) is in the unfolded state, the driving mechanism (420) drives the camera (410) to rotate around the first axis, the maximum rotation angle of the camera (410) around the first axis is a second angle, and the second angle is larger than the first angle.

5. The electronic device of claim 1, wherein the camera (410) is fixed relative to the first component (500) with the flexible display (300) in the collapsed state.

6. The electronic device of claim 1, wherein a first edge of the first housing (100) is provided with a winding shaft, a first segment of the flexible display (300) is wound around the winding shaft and is in sliding fit with the first housing (100), and the camera (410) is provided at the first edge.

7. The electronic device of claim 1, wherein the drive mechanism (420) drives the camera (410) to rotate about a first axis and a second axis with the flexible display (300) in the unfolded state, the first axis being perpendicular to the second axis.

8. The electronic device of claim 7, wherein the drive mechanism (420) comprises a first drive source (421) and a second drive source (422), the first drive source (421) and the second drive source (422) each being coupled to the camera (410), the first drive source (421) driving the camera (410) to rotate about the first axis, the second drive source (422) driving the camera (410) to rotate about the second axis.

9. The electronic device of claim 8, wherein the driving mechanism (420) further comprises a first rotating member (423), a second rotating member (424), a first rotating shaft (425) and a second rotating shaft (426), the first rotating member (423) and the second rotating member (424) are both rotatably connected to the first housing (100), one end of the first rotating shaft (425) is connected to the second rotating shaft (426), the other end of the first rotating shaft (425) is connected to the camera (410), the first rotating member (423) is sleeved outside the first rotating shaft (425), and the second rotating member (424) is sleeved outside the second rotating shaft (426);

the first driving source (421) drives the camera (410) to rotate around the axis of the second rotating shaft (426) through the first rotating shaft (425), and the second driving source (422) drives the camera (410) to rotate around the axis of the first rotating shaft (425) through the second rotating shaft (426).

10. The electronic device of claim 9, wherein the driving mechanism (420) further comprises a ball member (427), wherein one end of the first rotating shaft (425) is connected to the second rotating shaft (426) through the ball member (427), and wherein the ball member (427) is located between the first rotating member (423) and the second rotating member (424).

11. An electronic device according to claim 8, characterized in that the first drive source (421) has a first output shaft and the second drive source (422) has a second output shaft, the first output shaft being parallel to the first axis and the second output shaft being parallel to the second axis.

12. The electronic device of claim 8, wherein the driving mechanism (420) further comprises a driving belt (428), and the first driving source (421) drives the camera (410) to rotate through the driving belt (428).

13. The electronic device according to claim 8, wherein at least one of the first drive source (421) and the second drive source (422) is a vibration motor.

14. The electronic device of claim 1, further comprising a gyroscope (600), wherein the camera (410) has a light entrance end, and wherein the gyroscope (600) is disposed on a side of the camera (410) facing away from the light entrance end.