CN111726497A - Camera module and electronic equipment - Google Patents

Abstract

The application discloses module and electronic equipment make a video recording, the disclosed module of making a video recording includes module casing, camera lens, first drive arrangement and fluid portion, wherein: at least part of the lens is arranged in the module shell, a fluid part is filled between the outer wall of the lens and the inner wall of the module shell, the first driving device is arranged on the first side of the module shell, and the first driving device can drive the fluid part to flow; under the condition that the first driving device is in a first state, the first driving device drives the fluid part to flow in a direction away from the first side, and the fluid part drives the lens to move in a direction close to the first side; when the first driving device is in the second state, the first driving device drives the fluid part to flow to the first side, and the fluid part drives the lens to move in a direction away from the first side. The comparatively serious problem of wearing and tearing of module of making a video recording can be solved to above-mentioned scheme.

Description

Camera module and electronic equipment

Technical Field

The application relates to the technical field of camera devices, in particular to a camera module and electronic equipment.

Background

With the rapid development of electronic devices, the electronic devices are applied more and more widely, and the electronic devices such as mobile phones and tablet computers play more and more roles in the work, life, entertainment and the like of people. Particularly, with the development of internet social media in recent years, users are more and more concerned about the advantages and disadvantages of the image capturing function of the electronic device while pursuing a more convenient operating system of the electronic device.

Many people use electronic equipment to shoot or take a video nowadays, people can make the module shake of making a video recording because of factors such as hand shake or support vibrations in the in-process of shooing unavoidably, in case take place the shake, then the photo or the video of shooing out can be fuzzy, influence user experience. Therefore, how to solve the problem of shaking of the camera module in the using process is a difficult problem in the technical field of camera devices. At present, most electronic devices adopt an Optical imaging stabilization (OIS anti-shake) technology to avoid the situation that the imaging quality of the electronic devices is poor due to shake when shooting, and the shake of a camera module is compensated by moving or rotating a lens, so that the image can be kept stable.

However, when the camera module shakes at a high frequency, the lens needs to move or rotate at a high frequency to compensate for the shake of the camera module, and the lens needs to slide and rub against other parts of the camera module when moving or rotating, so that the lens and the other parts of the camera module are worn seriously, and particularly when the camera module shakes quickly, the lens and the other parts are worn seriously, so that the camera module is worn seriously, and the camera module has a short service life and low reliability.

Disclosure of Invention

The application discloses module and electronic equipment make a video recording can solve the comparatively serious problem of wearing and tearing of the module of making a video recording.

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

in a first aspect, an embodiment of the present application discloses a camera module, including a module housing, a lens, a first driving device and a fluid portion, wherein:

at least part of the lens is arranged in the module shell, the fluid part is filled between the outer wall of the lens and the inner wall of the module shell, the first driving device is arranged on the first side of the module shell, and the first driving device can drive the fluid part to flow;

under the condition that the first driving device is in a first state, the first driving device drives the fluid part to flow in the direction away from the first side, and the fluid part drives the lens to move in the direction close to the first side;

when the first driving device is in a second state, the first driving device drives the fluid part to flow to the first side, and the fluid part drives the lens to move in a direction away from the first side.

In a second aspect, an embodiment of the present application discloses an electronic device, which includes the above-mentioned camera module.

The technical scheme adopted by the application can achieve the following beneficial effects:

the utility model discloses a camera module, first drive arrangement can drive fluid portion and flow towards the direction that deviates from the first side, at this moment, fluid portion can drive the camera lens and move towards the direction that is close to the first side, first drive arrangement can drive fluid portion and flow towards the direction that is close to the first side, at this moment, fluid portion can drive the camera lens and move towards the direction that deviates from the first side, thereby make camera module can be according to the concrete shake of camera lens, realize the compensation to the camera lens, thereby make camera module have anti-shake's effect, and then make camera module also can shoot the higher photo of formation of image quality or video when shaking. Meanwhile, the fluid part can relieve the abrasion degree between the lens and other parts (such as a module shell) of the camera module, and prevent the lens from being seriously abraded with other parts of the camera module, so that the camera module can be prevented from being easily failed due to the serious abrasion between the lens and other parts, the reliability of the camera module is improved, and the service life of the camera module is prolonged.

Drawings

Fig. 1 is a schematic view of a camera module disclosed in an embodiment of the present application;

fig. 2 is a schematic view of a camera module disclosed in another embodiment of the present application;

fig. 3 is a schematic view of fig. 1 or fig. 2 from another viewing angle.

Description of reference numerals:

100-module housing, 110-through hole, 120-boss;

200-lens;

300-a first driving device, 310-a magnetic attraction block and 320-an electromagnet;

400-a fluid portion;

500-second drive means.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be described in detail and completely with reference to the following specific embodiments of the present application and the accompanying drawings. It is to be understood that the embodiments described are only a few embodiments of the present application and not all embodiments. 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 is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application are capable of operation in sequences other than those illustrated or described herein. The objects distinguished by "first", "second", and the like are usually a class, and the number of the objects is not limited, and for example, the first object may be one or a plurality of objects. 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 technical solutions disclosed in the embodiments of the present application are described in detail below with reference to the accompanying drawings through specific embodiments and application scenarios thereof.

Referring to fig. 1 to 3, an embodiment of the present application discloses a camera module, which includes a module housing 100, a lens 200, a first driving device 300, and a fluid portion 400.

Wherein, module casing 100 is the foundation member of the module of making a video recording, and module casing 100 can provide the installation basis for the other parts of the module of making a video recording. At least part of the lens 200 is disposed in the module housing 100, and light reflected by the object to be photographed enters the camera module through the lens 200, so that the camera module is subjected to photosensitive imaging, and the lens 200 can zoom, filter, deflect and the like on the light. The structure and operation principle of the lens 200 are known in the art, and are not described herein again for the sake of brevity.

The fluid portion 400 is filled between the outer wall of the lens 200 and the inner wall of the module housing 100, and specifically, a receiving cavity may be formed between the outer wall of the lens 200 and the inner wall of the module housing 100, and a fluid is disposed in the receiving cavity, so as to form the fluid portion 400, or a fluid is filled in the flexible film, and then the fluid portion 400 formed by the flexible film and the fluid is disposed between the outer wall of the lens 200 and the inner wall of the module housing 100, which is not limited in the embodiment of the present application.

The first driving device 300 is disposed on the first side of the module housing 100, and the first driving device 300 can drive the fluid portion 400 to flow. Specifically, the first driving device 300 may be disposed inside the module case 100 or outside the module case 100, and when the first driving device 300 is disposed in the module case 100, the driving part of the first driving device 300 penetrates the module case 100 so that the first driving device 300 can drive the fluid part 400 to flow.

The first driving device 300 has a first state and a second state, and when the first driving device 300 is in the first state, the first driving device 300 drives the fluid portion 400 to flow in a direction away from the first side, and the fluid portion 400 drives the lens 200 to move in a direction close to the first side. Specifically, the first driving device 300 may press the fluid portion 400, so that the fluid portion 400 may flow between an outer wall of the lens 200 and an inner wall of the module housing 100 in a direction away from the first side, so that the fluid portion 400 is gathered at the side of the module housing 100 away from the first side, and when the fluid portion 400 is gathered at the side of the module housing 100 away from the first side more and more, the increased fluid portion 400 may push the lens 200 to move in a direction close to the first side.

In the second state of the first driving device 300, the first driving device 300 drives the fluid portion 400 to flow to the first side, and the fluid portion 400 drives the lens 200 to move away from the first side. Specifically, the first driving device 300 may pull or suck the fluid portion 400, so that the fluid portion 400 may flow between the outer wall of the lens 200 and the inner wall of the module case 100 toward the first side, so that the fluid portion 400 is gathered at the first side of the module case 100, and when the portion of the fluid portion 400 gathered at the first side is gradually increased, the increased fluid portion 400 may push the lens 200 to move away from the first side.

In a specific using process, when the lens 200 needs to be compensated for a shake, the camera module may control the state of the first driving device 300 to move the lens 200, so as to compensate for the shake. Specifically, when the lens 200 moves away from the first side due to shaking, the camera module may control the first driving device 300 to be in the first state, so that the lens 200 moves toward the direction close to the first side, thereby implementing compensation for the lens 200; when the lens 200 moves towards the direction close to the first side due to shaking, the camera module may control the first driving device 300 to be in the second state, so that the lens 200 moves towards the direction away from the first side, thereby implementing compensation for the lens 200.

The utility model discloses a camera module, first drive arrangement 300 can drive fluid portion 400 and flow towards the direction that deviates from the first side, at this moment, fluid portion 400 can drive camera lens 200 and move towards the direction that is close to the first side, first drive arrangement 300 can drive fluid portion 400 and flow towards the direction that is close to the first side, at this moment, fluid portion 400 can drive camera lens 200 and move towards the direction that deviates from the first side, thereby make camera module can be according to the concrete shake of camera lens 200, realize the compensation to camera lens 200, thereby make camera module have anti-shake's effect, and then make camera module also can shoot the higher photo or the video of formation of image quality when shaking. Meanwhile, the fluid portion 400 can relieve the degree of wear between the lens 200 and other components of the camera module (for example, the module housing 100, but does not include the fluid portion 400, because the fluid portion 400 and the lens 200 are difficult to slide and rub), and prevent the lens 200 from being seriously worn with other components of the camera module, so that the camera module can be prevented from being easily lost due to serious wear between the lens 200 and other components, the reliability of the camera module is improved, and the service life of the camera module is prolonged.

In an alternative embodiment, the number of the first driving devices 300 may be multiple, multiple first driving devices 300 may be disposed at intervals around the optical axis of the lens 200 in the module housing 100, and each of the multiple first driving devices 300 may drive the fluid portion 400 to flow. The plurality of first driving devices 300 can drive the fluid part 400 to flow in a plurality of directions, so that the lens 200 can be driven to move in a plurality of directions, the lens 200 can be subjected to shake compensation in a plurality of directions, and the anti-shake performance of the camera module is further improved.

Further, the plurality of first driving devices 300 may be disposed in the module housing 100 at equal intervals around the optical axis of the lens 200, such that the plurality of first driving devices 300 are symmetrically disposed in the module housing 100, when the lens 200 shakes, the plurality of first driving devices 300 can compensate the lens 200 symmetrically, so that the compensation movement of the lens 200 is regular, and meanwhile, the plurality of first driving devices 300 are symmetrically disposed in the module housing 100, which is beneficial for a designer to write a control program, and reduces the difficulty of the designer to write the control program.

The number of the first driving devices 300 may be odd or even, which is not limited in the embodiment of the present application. In the case that the number of the first driving devices 300 is even, the plurality of first driving devices 300 are arranged opposite to each other, that is, the first driving devices 300 are arranged on both opposite sides of the lens 200, and when the lens 200 needs to be compensated in a certain direction, the two first driving devices 300 drive the lens 200 to move together, for example, the first driving devices 300 are arranged on both the first side and the side of the module case 100 away from the first side, and when the lens 200 needs to move in a direction close to the first side, the first driving device 300 on the first side may be in the first state, and the first driving device 300 on the other side may be in the second state. Under the combined action of two first drive arrangement 300, the velocity of motion of camera lens 200 can be improved undoubtedly to make the module of making a video recording compensate camera lens 200 sooner, simultaneously, the module of making a video recording can also carry out the compensation of higher frequency to camera lens 200 when the shake frequency is higher, further improves the anti-shake performance of the module of making a video recording.

In order to further reduce the wear between the lens 200 and other parts of the camera module, optionally, a photosensitive element may be disposed between the bottom of the lens 200 and the bottom wall of the module housing 100, and one of the bottom of the lens 200 and the bottom wall of the module housing 100 may be provided with a first magnetic member, and the other may be provided with a second magnetic member, where the first magnetic member and the second magnetic member magnetically repel each other to support the lens 200, so that the lens 200 is disposed in a floating manner, the contact area between the lens 200 and other parts of the camera module is reduced, and the wear between the lens 200 and other parts of the camera module can be further reduced. Meanwhile, the lens 200 in the floating arrangement has small resistance when moving, so that the fluid part 400 can better drive the lens 200 to move, and further the compensation effect of the lens 200 is better.

Specifically, the fluid portion 400 may be a fluid bag, and the fluid bag is disposed around the lens 200, so that the fluid portion 400 is filled between an outer wall of the lens 200 and an inner wall of the module housing 100, thereby achieving an anti-shake effect.

In another alternative embodiment, a photosensitive element and a fluid portion 400 may be disposed between the bottom of the lens 200 and the bottom wall of the module housing 100, the photosensitive element is disposed opposite to the lens 200, the fluid portion 400 surrounds the photosensitive element, and the fluid portion 400 supports the lens 200, so that the lens 200 is disposed in a floating manner, and thus, abrasion between the lens 200 and other components of the camera module can be further reduced. Meanwhile, the lens 200 in the floating arrangement has small resistance when moving, so that the fluid part 400 can better drive the lens 200 to move, and further the compensation effect of the lens 200 is better.

Of course, the camera module disclosed in the embodiment of the present application can implement the above two schemes simultaneously, that is, while the fluid portion 400 is disposed between the bottom of the lens 200 and the bottom wall of the module housing 100, one of the bottom of the lens 200 and the bottom wall of the module housing 100 may be provided with the first magnetic member, and the other may be provided with the second magnetic member, so that the floating effect of the lens 200 can be better.

In the case that the fluid portion 400 is disposed between the bottom of the lens 200 and the bottom wall of the module housing 100, the camera module may further include a second driving device 500, the second driving device 500 may be disposed on a side of the module housing 100 away from the lens 200, and the second driving device 500 may drive the fluid portion 400 to flow, specifically, the second driving device 500 may be disposed inside the module housing 100 or outside the module housing 100, and in the case that the second driving device 500 is disposed in the module housing 100, the driving portion of the second driving device 500 penetrates through the module housing 100, so that the second driving device 500 may drive the fluid portion 400 to flow.

The second driving device 500 has a third state and a fourth state, and when the second driving device 500 is in the third state, the second driving device 500 can drive the fluid portion 400 to flow in a direction away from the photosensitive element, and the fluid portion 400 drives the lens 200 to move away from the photosensitive element, specifically, the second driving device 500 can press the fluid portion 400 so that the fluid portion 400 flows in a direction away from the photosensitive element, and the fluid portion 400 drives the lens 200 to move away from the photosensitive element when flowing; in the case that the second driving device 500 is in the fourth state, the second driving device 500 drives the fluid portion 400 to flow toward the direction close to the photosensitive element, and the fluid portion 400 drives the lens 200 to flow toward the photosensitive element, specifically, the second driving device 500 may drive the second driving device 500 to flow toward the direction close to the photosensitive element, and the fluid portion 400 drives the lens 200 to flow toward the photosensitive element.

According to the working process, the second driving device 500 can realize focusing compensation on the lens 200, so that the lens 200 can focus light better, and meanwhile, the mode can also enable the focusing range of the lens 200 to be larger, so that the camera module can shoot in a long focus mode and in a short focus mode, and further the shooting effect of the camera module is enriched. The second driving device 500 may be a driving part having the same structure as the first driving device 300.

As described above, a photosensitive element and the fluid portion 400 may be disposed between the bottom of the lens 200 and the bottom wall of the module housing 100, so that the fluid portion 400 supports the lens 200 to avoid the fluid portion 400 from affecting the photosensitivity of the photosensitive element. Alternatively, the fluid portion 400 may be partially located between the photosensitive element and the lens 200 to support the lens 200, and the fluid portion 400 may be a light-transmissive fluid portion through which light can be transmitted, thereby making it difficult for the fluid portion 400 to affect the sensitivity of the photosensitive element. The light-permeable liquid ejecting section may be water or ethanol, and the like, which is not limited in the embodiment of the present application.

In another alternative embodiment, a photosensitive element and a flexible isolation ring are disposed between the bottom of the lens 200 and the bottom wall of the module housing 100, the photosensitive element is located in the flexible isolation ring, and two ends of the flexible isolation ring are respectively connected to the bottom wall of the module housing 100 and the lens 200, so that the flexible isolation ring, the bottom wall of the module housing 100 and the lens 200 form a light transmission channel, the fluid portion 400 is located outside the flexible isolation ring, that is, the fluid portion 400 is located outside the light transmission channel, light transmitted through the lens 200 passes through the light transmission channel and is received by the photosensitive element, and since the fluid portion 400 is located outside the light transmission channel, the fluid portion 400 is difficult to affect the light sensitivity of the photosensitive element.

In this embodiment, the first driving device 300 is disposed on a first side of the module housing 100, specifically, the module housing 100 may have a through hole 110, the through hole 110 is communicated with an inner cavity of the module housing 100, the first driving device 300 may include a magnetic attraction block 310 and an electromagnet 320, the magnetic attraction block 310 may be disposed in the through hole 110, the magnetic attraction block 310 is in sliding fit with the through hole 110, and the magnetic attraction block 310 is in sealing fit with the through hole 110, so that the magnetic attraction block 310 and the through hole 110 form a piston structure, the electromagnet 320 is disposed on a side of the magnetic attraction block 310 that can be away from the module housing 100, and the magnetic attraction block 310 is in magnetic fit with the electromagnet 320. When the first driving device 300 is in the first state, the electromagnet 320 is energized to magnetically repel the electromagnet 320 and the magnet block 310, so that the magnet block 310 presses the fluid portion 400; with the first driving device 300 in the second state, the electromagnet 320 is energized to magnetically attract the electromagnet 320 and the magnet block 310, so that the piston structure drives the fluid portion 400. The first driving device 300 has a simple structure, is reliable to drive, and is convenient to install.

Further, the module housing 100 may be provided with the protruding portion 120, the through hole 110 may be opened in the protruding portion 120, so that the depth dimension of the through hole 110 is large, thereby making the telescopic distance of the piston structure large, thereby making the driving distance of the first driving device 300 large, and further making the camera module compensate the lens 200 when the shake displacement is large, and the compensated displacement is large, so that the anti-shake range of the camera module is large.

Based on the module of making a video recording that this application embodiment disclosed, this application embodiment still discloses an electronic equipment, the electronic equipment that discloses include arbitrary embodiment of the above the module of making a video recording because the module of making a video recording has better anti-shake performance for electronic equipment also can shoot the higher photo of image quality or video even when the shake, and then promotes user's use and experiences.

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

In the embodiments of the present application, the difference between the embodiments is described in detail, and different optimization features between the embodiments can be combined to form a better embodiment as long as the differences are not contradictory, and further description is omitted here in view of brevity of the text.

The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (10)

1. The utility model provides a module of making a video recording which characterized in that, includes module casing, camera lens, a drive arrangement and fluid portion, wherein:

at least part of the lens is arranged in the module shell, the fluid part is filled between the outer wall of the lens and the inner wall of the module shell, the first driving device is arranged on the first side of the module shell, and the first driving device can drive the fluid part to flow;

under the condition that the first driving device is in a first state, the first driving device drives the fluid part to flow in the direction away from the first side, and the fluid part drives the lens to move in the direction close to the first side;

when the first driving device is in a second state, the first driving device drives the fluid part to flow to the first side, and the fluid part drives the lens to move in a direction away from the first side.

2. The camera module of claim 1, wherein the number of the first driving devices is plural, the plural first driving devices are disposed at intervals around an optical axis of the lens in the module housing, and each of the plural first driving devices can drive the fluid to flow.

3. The camera module of claim 2, wherein a plurality of the first driving devices are disposed at equal intervals around an optical axis of the lens in the module housing;

when the number of the first driving devices is even, the first driving devices are arranged in pairs.

4. The camera module of claim 1, wherein a photosensitive element is disposed between the bottom of the lens and the bottom wall of the module housing, and one of the bottom of the lens and the bottom wall of the module housing is provided with a first magnetic member and the other is provided with a second magnetic member, wherein the first magnetic member and the second magnetic member magnetically repel each other to support the lens.

5. The camera module of claim 1, wherein a light sensing element and the fluid portion are disposed between a bottom of the lens and a bottom wall of the module housing, the light sensing element being disposed opposite the lens, and the fluid portion surrounding the light sensing element, the fluid portion supporting the lens.

6. The camera module of claim 5, further comprising a second driving device disposed on a side of the module housing facing away from the lens, wherein the second driving device can drive the fluid to flow;

when the second driving device is in a third state, the second driving device drives the fluid part to flow towards a direction away from the photosensitive element, and the fluid part drives the lens away from the photosensitive element;

when the second driving device is in the fourth state, the second driving device drives the fluid portion to flow in a direction to approach the photosensitive element, and the fluid portion drives the lens to approach the photosensitive element.

7. The camera module of claim 1, wherein a light-sensing element and the fluid portion are disposed between a bottom of the lens and a bottom wall of the module housing, and the fluid portion is disposed between the light-sensing element and the lens to support the lens, the fluid portion being a light-transmissive fluid portion; or the like, or, alternatively,

the bottom of camera lens with be provided with photosensitive element and flexible cage between the diapire of module casing, photosensitive element is located in the flexible cage, just the both ends of flexible cage respectively with the diapire of module casing with the camera lens links to each other, the fluid position is in outside the flexible cage.

8. The camera module of claim 1, wherein the module housing defines a through hole, the through hole communicates with an inner cavity of the module housing, the first driving device includes a magnetic attraction block and an electromagnet, the magnetic attraction block is disposed in the through hole, the magnetic attraction block is slidably engaged with the through hole, the magnetic attraction block is sealingly engaged with the through hole, the electromagnet is disposed on a side of the magnetic attraction block facing away from the module housing, and the magnetic attraction block is magnetically engaged with the electromagnet.

9. The camera module of claim 8, wherein the module housing is provided with a boss, and the through hole opens into the boss.

10. An electronic apparatus, characterized by comprising the camera module of any one of claims 1 to 9.

Images