阅读说明：本技术 防抖结构、防抖系统及摄像装置 (Anti-shake structure, anti-shake system and camera device ) 是由 龚高峰 王建华 唐利新 于 2019-11-21 设计创作，主要内容包括：本发明提供了一种防抖结构、防抖系统及摄像装置。其中,防抖结构包括外壳和底座,外壳罩设在底座上并与底座之间形成容置空间,防抖结构还包括设置在容置空间内的透镜支撑体、驱动线圈、第一柔性PCB板、多个侧向线圈、多个驱动磁石、第二柔性PCB板和多个辅助线圈；驱动线圈绕设在透镜支撑体上,其中：第一柔性PCB板绕外壳的周向内侧壁设置,侧向线圈设置在第一柔性PCB板上；驱动磁石设置在透镜支撑体与第一柔性PCB板之间,且多个侧向线圈对应多个驱动磁石设置；第二柔性PCB板位于底座与透镜支撑体之间,辅助线圈设置在第二柔性PCB板上,且多个辅助线圈对应多个驱动磁石设置。本发明解决了现有技术中防抖系统防抖性能差以及占用空间大的问题。(The invention provides an anti-shake structure, an anti-shake system and a camera device. The anti-shake structure comprises a shell and a base, wherein the shell is covered on the base and forms an accommodating space with the base; the driving coil is wound on the lens support body, wherein: the first flexible PCB is arranged around the circumferential inner side wall of the shell, and the lateral coil is arranged on the first flexible PCB; the driving magnets are arranged between the lens supporting body and the first flexible PCB, and the plurality of lateral coils are arranged corresponding to the plurality of driving magnets; the second flexible PCB is located between the base and the lens supporting body, the auxiliary coils are arranged on the second flexible PCB, and the auxiliary coils correspond to the plurality of driving magnets. The invention solves the problems of poor anti-shake performance and large occupied space of the anti-shake system in the prior art.)

1. An anti-shake structure, comprising a housing (10) and a base (20), wherein the housing (10) covers the base (20) and forms an accommodating space with the base (20), and the anti-shake structure further comprises a lens support body (30), a driving coil (31), a first flexible PCB (40), a plurality of lateral coils (41), a plurality of driving magnets (11), a second flexible PCB (50) and a plurality of auxiliary coils (51) arranged in the accommodating space, wherein:

the driving coil (31) is wound on the lens supporting body (30);

the first flexible PCB (40) is arranged around the circumferential inner side wall of the shell (10), and the lateral coil (41) is arranged on the first flexible PCB (40);

the driving magnet (11) is arranged between the lens support body (30) and the first flexible PCB (40), and the plurality of lateral coils (41) are arranged corresponding to the plurality of driving magnets (11);

the second flexible PCB (50) is located between the base (20) and the lens support body (30), the auxiliary coil (51) is arranged on the second flexible PCB (50), and the auxiliary coil (51) is arranged corresponding to the drive magnets (11).

2. The anti-shake structure according to claim 1,

at least a portion of the lateral coil (41) is embedded inside the first flexible PCB board (40); and/or

At least a portion of the auxiliary coil (51) is embedded inside the second flexible PCB (50).

3. The anti-shake structure according to claim 1, wherein, of the plurality of lateral coils (41), two of the lateral coils (41) that are disposed opposite to each other are electrically connected to each other, and the lateral coil (41) and the auxiliary coil (51) that correspond to the same drive magnet (11) are electrically connected to each other.

4. Anti-shake structure according to claim 3, characterised in that the base (20) has a coil pin group (21), and the auxiliary coil (51) is electrically connected to the coil pin group (21).

5. The anti-shake structure according to claim 4, wherein a plurality of welding grooves (42) are disposed on a set of two opposite sidewalls of the first flexible PCB (40), the plurality of welding grooves (42) correspond to the plurality of lateral coils (41), a plurality of welding protrusions (52) matched with the plurality of welding grooves (42) are disposed on the second flexible PCB (50), the first flexible PCB (40) and the second flexible PCB (50) are welded by the welding grooves (42) and the welding protrusions (52) to realize the electrical connection between the lateral coils (41) and the auxiliary coils (51), and an avoiding opening (12) is disposed at a position of the housing (10) corresponding to the welding protrusions (52).

6. The anti-shake structure according to claim 4, wherein the base (20) and the second flexible PCB board (50) are soldered to electrically connect the auxiliary coil (51) and the coil pin set (21).

7. Anti-shake structure according to claim 4, characterised in that the base (20) has a first relief opening (22) in its centre, the circumferential side wall of the first abdicating opening (22) is provided with a plurality of first welding gaps (23), the center of the second flexible PCB (50) is provided with a second abdicating opening (53), the circumferential side wall of the second abdicating opening (53) has a plurality of second welding notches (54) cooperating with the plurality of first welding notches (23), the base (20) is also internally provided with a communication component (24) electrically connected with the coil pin group (21), at least a portion of the communication assembly (24) protrudes from the first weld notch (23), the connecting wire of the auxiliary coil (51) extends out of the second welding notch (54), and the communication component (24) is welded with the connecting wire.

8. The anti-shake structure according to claim 7, wherein the auxiliary coils (51) are four, the communication assembly (24) includes a first communication body (241), a second communication body (242), a third communication body (243), and a fourth communication body (244), the coil pin group (21) includes a first coil pin (211), a second coil pin (212), a third coil pin (213), and a fourth coil pin (214), the first communication body (241) is electrically connected with the first coil pin (211), the second communication body (242) is electrically connected with the second coil pin (212), the third communication body (243) is electrically connected with the third coil pin (213), the fourth communication body (244) is electrically connected with the fourth coil pin (214), and the first communication body (241) and the third communication body (243) are electrically connected with a group of opposing auxiliary coils (51), respectively, the second via (242) and the fourth via (244) are connected to the auxiliary coil (51) facing each other in another group.

9. Anti-shake structure according to claim 8, characterized in that the first coil pin (211), the second coil pin (212), the third coil pin (213) are located on the same side of the base (20), and the fourth coil pin (214) is located on the opposite side of the base (20) where the second coil pin (212) is located.

10. The anti-shake structure according to any one of claims 1 to 9,

a positioning hole (55) is formed in the second flexible PCB (50), and a positioning bulge (25) matched with the positioning hole (55) is formed in the base (20); and/or

The shell (10) is provided with an overlapping notch (14), an overlapping protrusion (26) matched with the overlapping notch (14) is arranged on the base (20), and at least one part of the overlapping protrusion (26) is in contact with and supports the surface of the overlapping notch (14).

11. The anti-shake structure according to any one of claims 1 to 9, further comprising:

the Hall chip (60) is used for sensing the driving magnet (11), the Hall chip (60) is arranged on one side, facing the second flexible PCB (50), of the base (20), the base (20) is provided with a concave part used for accommodating the Hall chip (60), and the second flexible PCB (50) is provided with an avoidance notch (29) which avoids the Hall chip (60);

the base comprises a Hall chip pin group (27), wherein the Hall chip pin group (27) is arranged on the base (20), and the Hall chip (60) is electrically connected with the Hall chip pin group (27).

12. The anti-shake structure according to any one of claims 1 to 9, further comprising:

a support frame (70), wherein the drive magnet (11) is arranged on the support frame (70), and the support frame (70) is positioned between the lens support body (30) and the first flexible PCB (40);

an upper spring (80), an outer corner of the upper spring (80) being connected at an upper surface of the support frame (70), an inner side of the upper spring (80) being connected at an upper surface of the lens support body (30);

a lower spring (90) connected at an outer corner of the lower spring (90) at a lower surface of the support frame (70), an inner-ring side of the lower spring (90) being connected at a lower surface of the lens support body (30);

the suspension wire fixing structure comprises a plurality of suspension wires (100), wherein one suspension wire (100) is correspondingly arranged at the corner of each base (20), each suspension wire (100) sequentially penetrates through the base (20), the second flexible PCB (50) and the upper spring (80), and the corners of the lower spring (90) and the corners of the supporting frame (70) are provided with yielding concave parts for avoiding the suspension wires (100).

13. The anti-shake structure according to claim 12, wherein the base (20) further has a first suspension pin (28) and a second suspension pin (281), and the first suspension pin (28) and the second suspension pin (281) are electrically connected to two adjacent suspension wires (100), respectively.

14. The anti-shake structure according to claim 13, wherein the upper spring (80) includes a first sub-spring (81) and a second sub-spring (82), the first sub-spring (81) is in electrical communication with the first suspension wire pin (28) through the suspension wire (100), the second sub-spring (82) is in electrical communication with the second suspension wire pin (281) through the suspension wire (100), and the first sub-spring (81) and the second sub-spring (82) are in electrical communication through the drive coil (31).

15. An anti-shake system, characterized by comprising the anti-shake structure according to any one of claims 1 to 14.

16. An image pickup apparatus comprising the anti-shake system according to claim 15.

Technical Field

The invention relates to the field of camera equipment, in particular to an anti-shake structure, an anti-shake system and a camera device.

Background

Photos shot by electronic equipment such as a mobile phone and the like in the shooting process sometimes become invalid, namely, the shot pictures are not clear enough, and double images or blurs occur. These causes, in addition to occasional defocus (i.e., failure of the imaging lens to be in focus), are largely due to slight jitter occurring when the photographic subject is exposed. In general, such a very slight shaking phenomenon often occurs in a handheld condition, and thus, in recent years, there is a relatively large demand for developing an anti-shaking function. Under the background, proposals for the optical anti-shake function of OIS (optical image stabilization system) are increasing, and the micro optical anti-shake technology is gradually adopted by various high-end mobile phones, so that it is expected to effectively reduce the probability of taking blurred pictures in a low-light environment and effectively solve the trouble caused by hand shake in the shooting process. However, compared to a general auto-focus motor, the design of the OIS optical anti-shake apparatus is complicated, and the production efficiency and yield are low, so the development is difficult.

In the conventional OIS, the overall height is high, the anti-shake performance is poor, the occupied space is large, and the anti-shake driving force is small. Therefore, the problems of poor anti-shake performance and large occupied space of the anti-shake system exist in the prior art.

Disclosure of Invention

The invention mainly aims to provide an anti-shake structure, an anti-shake system and a camera device, and aims to solve the problems that the anti-shake system in the prior art is poor in anti-shake performance and large in occupied space.

In order to achieve the above object, according to one aspect of the present invention, there is provided an anti-shake structure, including a housing and a base, the housing being covered on the base and forming an accommodating space with the base, the anti-shake structure further including a lens support body disposed in the accommodating space, a driving coil, a first flexible PCB, a plurality of lateral coils, a plurality of driving magnets, a second flexible PCB, and a plurality of auxiliary coils; the driving coil is wound on the lens support body, wherein: the first flexible PCB is arranged around the circumferential inner side wall of the shell, and the lateral coil is arranged on the first flexible PCB; the driving magnets are arranged between the lens supporting body and the first flexible PCB, and the plurality of lateral coils are arranged corresponding to the plurality of driving magnets; the second flexible PCB is located between the base and the lens supporting body, the auxiliary coils are arranged on the second flexible PCB, and the auxiliary coils correspond to the plurality of driving magnets.

Further, at least one part of the lateral coil is embedded in the first flexible PCB; and/or at least a portion of the auxiliary coil is embedded inside the second flexible PCB board.

Furthermore, two opposite lateral coils in the plurality of lateral coils are electrically connected, and the lateral coil corresponding to the same driving magnet is electrically connected with the auxiliary coil.

Furthermore, the base is provided with a coil pin group, and the auxiliary coil is electrically connected with the coil pin group.

Further, a plurality of welding grooves are formed in a group of two opposite side walls of the first flexible PCB, the plurality of welding grooves correspond to the plurality of lateral coils, a plurality of welding protrusions matched with the plurality of welding grooves are formed in the second flexible PCB, the first flexible PCB and the second flexible PCB are welded through the welding grooves and the welding protrusions, electric connection between the lateral coils and the auxiliary coils is achieved, and avoidance openings are formed in positions, corresponding to the welding protrusions, of the shell.

Further, the base and the second flexible PCB are welded to achieve the purpose that the auxiliary coil is electrically connected with the coil pin group.

Furthermore, the center of base has the first opening of stepping down, the first open-ended circumference lateral wall of stepping down has a plurality of first welding breach, the center of second flexible PCB board has the second opening of stepping down, the second open-ended circumference lateral wall of stepping down has with a plurality of second welding breach of a plurality of first welding breach complex, the inside of base still has the intercommunication subassembly of being connected with coil pin group electricity, at least a part of intercommunication subassembly is stretched out by first welding breach, auxiliary coil's connecting wire is stretched out by second welding breach, intercommunication subassembly and connecting wire welding.

Furthermore, the number of the auxiliary coils is four, the communication assembly comprises a first communication body, a second communication body, a third communication body and a fourth communication body, the coil pin group comprises a first coil pin, a second coil pin, a third coil pin and a fourth coil pin, the first communication body is electrically connected with the first coil pin, the second communication body is electrically connected with the second coil pin, the third communication body is electrically connected with the third coil pin, the fourth communication body is electrically connected with the fourth coil pin, the first communication body and the third communication body are respectively electrically connected with one group of opposite auxiliary coils, and the second communication body and the fourth communication body are respectively connected with the other group of opposite auxiliary coils.

Furthermore, the first coil pin, the second coil pin and the third coil pin are located on the same side of the base, and the fourth coil pin is located on the opposite side of the base where the second coil pin is located.

Furthermore, a positioning hole is formed in the second flexible PCB, and a positioning bulge matched with the positioning hole is formed in the base; and/or the shell is provided with an overlap gap, the base is provided with an overlap protrusion matched with the overlap gap, and at least one part of the overlap protrusion is in contact support with the surface of the overlap gap.

Further, the anti-shake structure still includes: the Hall chip is arranged on one side, facing the second flexible PCB, of the base, the base is provided with a concave part used for containing the Hall chip, and the second flexible PCB is provided with an avoidance notch for avoiding the Hall chip; the Hall chip pin group is arranged on the base, and the Hall chip is electrically connected with the Hall chip pin group.

Further, the anti-shake structure still includes: the driving magnet is arranged on the supporting frame, and the supporting frame is positioned between the lens supporting body and the first flexible PCB; the outer side corner of the upper spring is connected to the upper surface of the support frame, and the inner side of the upper spring is connected to the upper surface of the lens support body; a lower spring, the outer corner of the lower spring is connected with the lower surface of the support frame, and the inner ring side of the lower spring is connected with the lower surface of the lens support body; the base, the flexible PCB board of second and last spring are passed in proper order to a plurality of suspension wires, and the bight department of each base all corresponds and is provided with a suspension wire, and each suspension wire just has the recess of stepping down that is used for dodging the suspension wire with braced frame's bight.

Furthermore, the base is also provided with a first suspension wire pin and a second suspension wire pin, and the first suspension wire pin and the second suspension wire pin are respectively and electrically connected with two adjacent suspension wires.

Further, the upper spring includes a first sub-spring and a second sub-spring, the first sub-spring is electrically conducted with the first suspension wire pin through the suspension wire, the second sub-spring is electrically conducted with the second suspension wire pin through the suspension wire, and the first sub-spring and the second sub-spring are electrically conducted through the driving coil.

According to another aspect of the present invention, there is provided an anti-shake system comprising the anti-shake structure described above.

According to another aspect of the present invention, there is provided an image pickup apparatus including the above-described anti-shake system.

By applying the technical scheme, the anti-shake structure comprises a shell and a base, wherein the shell is covered on the base and forms an accommodating space with the base; the driving coil is wound on the lens support body, wherein: the first flexible PCB is arranged around the circumferential inner side wall of the shell, and the lateral coil is arranged on the first flexible PCB; the driving magnets are arranged between the lens supporting body and the first flexible PCB, and the plurality of lateral coils are arranged corresponding to the plurality of driving magnets; the second flexible PCB is located between the base and the lens supporting body, the auxiliary coils are arranged on the second flexible PCB, and the auxiliary coils correspond to the plurality of driving magnets.

With the anti-shake structure having the above structure, firstly, the lateral coil and the driving magnet are provided, so that the anti-shake function in the X/Y axial direction of the first gravity can be achieved by the interaction between the lateral coil and the driving magnet. And because the auxiliary coil is arranged, the auxiliary coil and the driving magnet interact with each other when the lateral coil and the driving magnet interact with each other, so that the X/Y axial anti-shaking effect of two gravities is achieved, and the whole anti-shaking effect and the actual force of the anti-shaking structure are comprehensively improved. Realize that the side direction coil unites auxiliary coil and drive magnetite to take effect jointly, produce the stack formula anti-shake drive effect of dual effort in the X/Y axial, simultaneously, on the basis that satisfies the required basic drive power of X/Y axial anti-shake, to reducing component size improvements such as side direction coil and drive magnetite to and at the whole size of adjustment anti-shake structure, the miniaturization of the whole volume of product, frivolousization aspect has created extremely favorable transformation space.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 shows a schematic structural diagram of an anti-shake structure according to an embodiment of the invention;

fig. 2 shows a cross-sectional view of the anti-shake structure of fig. 1;

fig. 3 shows an exploded view of the anti-shake structure of fig. 1;

fig. 4 is a schematic diagram illustrating a positional relationship between the first flexible PCB and the lens support of the anti-shake structure of fig. 1;

fig. 5 is a schematic diagram illustrating a positional relationship between the second flexible PCB, the upper spring, and the lens support of the anti-shake structure of fig. 1;

fig. 6 shows a schematic structural view of a first flexible PCB board of the anti-shake structure of fig. 1;

fig. 7 is a schematic diagram showing a positional relationship of a lateral coil in the inside of the first flexible PCB of fig. 6;

fig. 8 is a schematic view illustrating an internal structure of the first flexible PCB of fig. 6;

fig. 9 is a schematic structural view illustrating a second flexible PCB of the anti-shake structure of fig. 1;

fig. 10 is a schematic view showing an internal structure of the second flexible PCB of fig. 9;

fig. 11 is a schematic diagram showing a positional relationship between a base and a hall chip of the anti-shake structure in fig. 1;

fig. 12 is a schematic diagram illustrating a positional relationship between a communication member and a coil pin group of the anti-shake structure of fig. 1;

fig. 13 is a schematic diagram showing a positional relationship among an auxiliary coil, a communicating member, and a coil pin group of the anti-shake structure of fig. 1;

fig. 14 is a schematic diagram illustrating a positional relationship among the lateral coil, the auxiliary coil, the communicating member, and the coil pin group of the anti-shake structure of fig. 1.

Wherein the figures include the following reference numerals:

10. a housing; 11. a drive magnet; 12. avoiding the opening; 13. dispensing a glue port; 14. overlapping the notches; 20. a base; 21. a coil pin group; 211. a first coil pin; 212. a second coil pin; 213. a third coil pin; 214. a fourth coil pin; 22. a first abdication opening; 23. a first weld notch; 24. a communicating component; 241. a first communicating body; 242. a second via; 243. a third via; 244. a fourth via; 25. positioning the projection; 26. overlapping the bulges; 27. a Hall chip pin group; 271. positioning a pin; 28. a first suspension wire pin; 281. a second suspension wire pin; 29. avoiding the notch; 30. a lens support; 31. a drive coil; 40. a first flexible PCB board; 41. a lateral coil; 42. welding the groove; 50. a second flexible PCB board; 51. an auxiliary coil; 52. welding a bump; 53. a second abdication opening; 54. a second weld notch; 55. positioning holes; 60. a Hall chip; 70. a support frame; 80. an upper spring; 81. a first sub-spring; 82. a second sub-spring; 90. A lower spring; 100. and (4) suspending the filaments.

Detailed Description

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.

It is noted that, unless otherwise indicated, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

In the present invention, unless specified to the contrary, use of the terms of orientation such as "upper, lower, top, bottom" or the like, generally refer to the orientation as shown in the drawings, or to the component itself in a vertical, perpendicular, or gravitational orientation; likewise, for ease of understanding and description, "inner and outer" refer to the inner and outer relative to the profile of the components themselves, but the above directional words are not intended to limit the invention.

In order to solve the problems of poor anti-shake performance and large occupied space of an anti-shake system in the prior art, the application provides an anti-shake structure, an anti-shake system and a camera device.

The camera device comprises an anti-shake system, and the anti-shake system comprises an anti-shake structure. Through using the anti-shake system in this application, can improve camera device's anti-shake performance effectively, avoid appearing using camera device to shoot out fuzzy, unclear image.

As shown in fig. 1 to 11, the anti-shake structure in the present application includes a housing 10 and a base 20, the housing 10 is covered on the base 20 and forms an accommodating space with the base 20, and the anti-shake structure further includes a lens support 30, a driving coil 31, a first flexible PCB 40, a plurality of lateral coils 41, a plurality of driving magnets 11, a second flexible PCB 50 and a plurality of auxiliary coils 51, which are disposed in the accommodating space; the driving coil 31 is wound on the lens support 30, wherein: the first flexible PCB 40 is disposed around the circumferential inner side wall of the housing 10, and the lateral coil 41 is disposed on the first flexible PCB 40; the driving magnets 11 are arranged between the lens support body 30 and the first flexible PCB 40, and the plurality of lateral coils 41 are arranged corresponding to the plurality of driving magnets 11; the second flexible PCB 50 is disposed between the base 20 and the lens support 30, the auxiliary coils 51 are disposed on the second flexible PCB 50, and the plurality of auxiliary coils 51 are disposed corresponding to the plurality of driving magnets 11.

With the anti-shake structure having the above-described structure, since the lateral coil 41 and the drive magnet 11 are provided, the X/Y axis anti-shake effect of the first gravity can be achieved by the interaction between the lateral coil 41 and the drive magnet 11. Because the auxiliary coil 51 is also arranged, the auxiliary coil 51 interacts with the driving magnet 11 while the lateral coil 41 interacts with the driving magnet 11, so that the X/Y axial anti-shaking effect of two-gravity is achieved, and the whole anti-shaking effect of the anti-shaking structure is comprehensively improved. The combined action of the auxiliary coil 51 and the driving magnet 11 of the lateral coil 41 is realized, the stacked anti-shake driving effect of double acting force is generated in the X/Y axial direction, and meanwhile, on the basis of meeting the basic driving force required by the X/Y axial anti-shake, extremely favorable transformation space is created for reducing the size improvement of the components such as the lateral coil 41 and the driving magnet 11, adjusting the whole size of an anti-shake structure, and reducing the whole volume of a product in the aspects of miniaturization and lightness and thinness.

As shown in fig. 8, at least a portion of the lateral coil 41 is embedded inside the first flexible PCB board 40.

As shown in fig. 10, at least a portion of the auxiliary coil 51 is embedded inside the second flexible PCB 50.

For driven anti-shake structure, have side direction coil 41 and auxiliary coil 51 simultaneously in this application, so the connecting wire between side direction coil 41 and the auxiliary coil 51 is relatively more, so through setting up side direction coil 41 and auxiliary coil 51 inside first flexible PCB board 40 and second flexible PCB board 50 respectively, can guarantee that the inside line of walking of anti-shake structure is more neat to can prevent the connecting wire winding or damage between side line coil or the auxiliary coil 51 that lead to because of vibrations.

As shown in fig. 7 and 14, two of the plurality of side coils 41 that are disposed opposite to each other are electrically connected to each other, and the side coil 41 and the auxiliary coil 51 that correspond to the same drive magnet 11 are electrically connected to each other. In the present application, the lateral coil 41 and the auxiliary coil 51 simultaneously act on the drive magnet 11. Therefore, by doing so, the electrical connection between the side coil 41 and the auxiliary coil 51 can be made easier.

As shown in fig. 4, 12, 13, and 14, the base 20 includes a coil pin group 21, and the auxiliary coil 51 is electrically connected to the coil pin group 21. Since the auxiliary coil 51 and the side coil 41 are electrically connected to each other, the coil lead group 21, the auxiliary coil 51, and the side coil 41 can be electrically connected to each other.

As shown in fig. 6 and 9, a plurality of welding grooves 42 are disposed on a set of two opposite sidewalls of the first flexible PCB 40, the plurality of welding grooves 42 correspond to the plurality of lateral coils 41, a plurality of welding protrusions 52 matched with the plurality of welding grooves 42 are disposed on the second flexible PCB 50, the first flexible PCB 40 and the second flexible PCB 50 are welded by the welding grooves 42 and the welding protrusions 52 to realize electrical connection between the lateral coils 41 and the auxiliary coils 51, and an avoiding opening 12 is disposed at a position of the housing 10 corresponding to the welding protrusions 52. It should be noted here that the plurality of soldering bumps 52 are also corresponding to the plurality of auxiliary coils 51, respectively, and by this arrangement, not only the stability between the first flexible PCB 40 and the second flexible PCB 50 but also the electrical connection between different lateral coils 41 and different auxiliary coils 51 can be effectively ensured, and also the short circuit of the adjacent lateral coils 41 or the adjacent auxiliary coils 51 can be prevented. And after the welding between the welding groove 42 and the welding projection 52 is completed, glue can be applied to the avoiding opening 12 for sealing.

It should be further noted that a plurality of dispensing ports 13 are further disposed on the side wall of the housing 10 corresponding to the first flexible PCB 40, and the housing 10 and the first flexible PCB 40 can be reinforced by dispensing to the dispensing ports 13.

Specifically, the base 20 and the second flexible PCB 50 are soldered to electrically connect the auxiliary coil 51 and the coil pin group 21.

Of course, the connection between the base 20 and the second flexible PCB board 50 may also be achieved by soldering between the auxiliary coil 51 and the coil pin group 21.

In the present application, as shown in fig. 9 to 11, a first abdicating opening 22 is formed in the center of the base 20, a plurality of first welding notches 23 are formed in a circumferential side wall of the first abdicating opening 22, a second abdicating opening 53 is formed in the center of the second flexible PCB 50, a plurality of second welding notches 54 matched with the plurality of first welding notches 23 are formed in a circumferential side wall of the second abdicating opening 53, a communication component 24 electrically connected to the coil lead group 21 is further formed in the base 20, at least a portion of the communication component 24 extends from the first welding notches 23, a connection line of the auxiliary coil 51 extends from the second welding notches 54, and the communication component 24 is welded to the connection line. By providing the first and second relief openings 22, 53, the movement of the lens support 30 can be effectively relieved. And by this arrangement, it is also possible to secure flatness between the base 20 and the second flexible PCB board 50 while achieving electrical connection between the auxiliary coil 51 and the coil pin group 21.

In one embodiment of the present application, the number of the auxiliary coils 51 is four, the communication assembly 24 includes a first communication body 241, a second communication body 242, a third communication body 243, and a fourth communication body 244, the coil pin group 21 includes a first coil pin 211, a second coil pin 212, a third coil pin 213, and a fourth coil pin 214, the first communication body 241 is electrically connected to the first coil pin 211, the second communication body 242 is electrically connected to the second coil pin 212, the third communication body 243 is electrically connected to the third coil pin 213, the fourth communication body 244 is electrically connected to the fourth coil pin 214, the first communication body 241 and the third communication body 243 are electrically connected to one group of the opposite auxiliary coils 51, respectively, and the second communication body 242 and the fourth communication body 244 are electrically connected to the other group of the opposite auxiliary coils 51, respectively.

In the present application, the electrical connection paths between the coil pin group 21, the auxiliary coil 51, and the lateral coil 41 are: the first coil leg 211 (or the second coil leg 212) -the first via 241 or the second via 242-the auxiliary coil 51-the lateral coil 41-the auxiliary coil 51-the third via 243 or the fourth via 244-the third coil leg 213 (or the fourth coil leg 214).

Specifically, the first coil pin 211, the second coil pin 212, and the third coil pin 213 are located on the same side of the base 20, and the fourth coil pin 214 is located on an opposite side of the base 20 from the second coil pin 212. With this arrangement, the distribution of the via assemblies between the coil lead group 21 and the auxiliary coil 51 inside the base 20 can be made more uniform. And can also guarantee effectively through setting up like this that the density value of base 20 everywhere is more even to can guarantee that anti-shake structure work in-process base 20 is more balanced.

Specifically, the second flexible PCB 50 is provided with a positioning hole 55, and the base 20 is provided with a positioning protrusion 25 engaged with the positioning hole 55. By so doing, it is possible to further effectively secure stability between the second flexible PCB 50 and the base 20 and reduce shaking between the second flexible PCB 50.

Specifically, the housing 10 has the overlapping notch 14, and the base 20 is provided with an overlapping protrusion 26 which is matched with the overlapping notch 14, and at least a part of the overlapping protrusion 26 is supported in contact with the surface of the overlapping notch 14. By such arrangement, the stability between the housing 10 and the base 20 can be ensured, so that the housing 10 and the base 20 are more attached to each other. And, this can also reduce the whole size of anti-shake structure effectively.

Specifically, the anti-shake structure further includes a support frame 70, an upper spring 80, a lower spring 90, and a plurality of suspension wires 100. The driving magnet 11 is disposed on the supporting frame 70, and the supporting frame 70 is located between the lens supporting body 30 and the first flexible PCB 40; the outer corners of the upper springs 80 are connected at the upper surface of the support frame 70, and the inner sides of the upper springs 80 are connected at the upper surface of the lens support body 30; the outer corner of the lower spring 90 is connected at the lower surface of the support frame 70, and the inner-ring side of the lower spring 90 is connected at the lower surface of the lens support body 30; the corner of each base 20 is correspondingly provided with a suspension wire 100, each suspension wire 100 sequentially passes through the base 20, the second flexible PCB 50 and the upper spring 80, and the corner of the lower spring 90 and the corner of the support frame 70 are provided with an abdicating recess for avoiding the suspension wire 100. Through setting up spring 80 and lower spring 90, can maintain the electricity of whole anti-shake structure and connect to can guarantee anti-shake drive arrangement's stable work. Meanwhile, the upper and lower springs 90 are effectively engaged and supported to the support frame 70 and the lens support 30 to form a whole, so that the support frame 70 and the lens support 30 tend to be in synchronous coordination consistency in the position compensation of the X \ Y axial direction, and the synchronous coordination consistency does not hinder the normal driving operation of the lens support 30 in the Z-axis optical axis direction.

Specifically, the base 20 also has a first suspension pin 28 and a second suspension pin 281, and the first suspension pin 28 and the second suspension pin 281 are electrically connected to two adjacent suspension wires 100, respectively.

Specifically, the upper spring 80 includes a first sub-spring 81 and a second sub-spring 82, the first sub-spring 81 is electrically conducted to the first suspension pin 28 through the suspension wire 100, the second sub-spring 82 is electrically conducted to the second suspension pin 281 through the suspension wire 100, and the first sub-spring 81 and the second sub-spring 82 are electrically conducted through the driving coil 31.

In one specific embodiment of the present application, the electrical connection paths between the first suspension pin 28, the second suspension pin 281, the upper spring 80, the suspension wire 100, and the driving coil 31 are: the first suspension wire pin 28 (or the second suspension wire pin 281) -the suspension wire 100 connecting the first suspension wire pin 28 and the first sub-spring 81 (or the suspension wire 100 connecting the second suspension wire pin 281 and the second sub-spring 82) -the first sub-spring 81 (or the second sub-spring 82) -the driving coil 31-the second sub-spring 82 (or the first sub-spring 81) -the suspension wire 100 connecting the second suspension wire pin 281 and the second sub-spring 82 (or the suspension wire 100 connecting the first suspension wire pin 28 and the first sub-spring 81) -the second suspension wire pin 281 (or the first suspension wire pin 28).

It should be noted that in the above-mentioned electrical connection process, the first sub-spring 81 (or the second sub-spring 82) is electrically connected to the driving coil 31 through the winding post of the lens support 30.

It should be noted that, in an embodiment of the present application, the anti-shake structure has four suspension wires 100, and the four suspension wires 100 are respectively located at four corners of the base 20, and a group of two adjacent suspension wires 100 are respectively electrically connected to the first suspension wire pin 28 and the second suspension wire pin 281, and the first suspension wire pin 28, the second suspension wire pin 281, and the suspension wires 100 respectively connected to the first suspension wire pin 28 and the second suspension wire pin 281 are all in the same plane.

In the present application, as shown in fig. 9 and 11, the anti-shake structure further includes a hall chip 60 and a hall chip pin group 27 for inductively driving the magnet 11. The hall chip 60 is arranged on one side of the base 20 facing the second flexible PCB 50, the base 20 is provided with a concave part for accommodating the hall chip 60, and the second flexible PCB 50 is provided with an avoiding notch 29 for avoiding the hall chip 60; the hall chip pin group 27 is disposed on the base 20, and the hall chip 60 is electrically connected to the hall chip pin group 27.

By providing the hall chip 60, the hall chip 60 can induce feedback of the position signal of the driving magnet 11, thereby calculating the offset of the lens support 30, further calculating the magnitude of the current applied to the lateral coil 41 and the auxiliary coil 51 according to the offset of the lens support 30, and making the lateral coil 41 and the auxiliary coil 51 interact with the driving magnet 11 to generate electromagnetic force, driving the supporting frame 70 by the electromagnetic force, and driving the lens support 30 to generate displacement by the supporting frame 70, so that the generated displacement corrects the offset of the lens support 30.

In the present embodiment, the number of the hall chips 60 is 2, and the two hall chips 60 respectively sense the position deviation of the lens support 30 in the X axis and the Y axis, thereby forming a closed-loop position sensing system. Also, the number of recesses provided on the base 20 for accommodating the hall chips 60 corresponds one-to-one to the hall chips 60, and two recesses on the base 20 are provided with respect to the X axis and the Y axis, respectively, and the positions of the two recesses should be as far apart as possible. Therefore, the driving magnet 11 can be effectively prevented from interfering the hall chip 60, and the feedback of the hall chip 60 to the displacement signal is influenced.

In addition, in the present embodiment, the hall chip pin group 27 has 8 positioning pins 271, wherein 4 positioning pins 271 are led to the hall chip 60 along the X-axis direction, and the other 4 positioning pins 271 are led to the hall chip 60 along the Y-axis direction. Each hall chip 60 requires both positive and negative poles and also requires input and output of signals of each pole, so at least 4 positioning pins 271 are required for each hall chip 60.

It should be noted that there are a total of 14 pins in the present application, including the first coil pin 211, the second coil pin 212, the third coil pin 213, the fourth coil pin 214, the first suspension pin 28, the second suspension pin 281, and the 8 positioning pins 271. And 14 pins are located on one set of two opposite sides of the base 20.

In an embodiment of the present application, two opposite sides of the base 20 are respectively provided with 7 pins, wherein 6 of the 7 pins on one side are the positioning pin 271 and the fourth coil pin 214, the first pin and the last pin of the 7 pins on the other side are the first suspension pin 28 and the second suspension pin 281, respectively, and the other 5 pins are the first coil pin 211, the second coil pin 212, the third coil pin 213 and the positioning pin 271.

By using the anti-shake structure in the present application, the auxiliary coil 51 and the driving magnet 11 can be jointly acted by the lateral coil 41, so as to improve the driving force in the X/Y axis direction of the anti-shake structure, i.e., improve the lateral thrust of the anti-shake structure.

From the above description, it can be seen that the above-described embodiments of the present invention achieve the following technical effects:

1. the anti-shake performance of the anti-shake structure is effectively improved;

2. the space occupied by the anti-shake structure is reduced;

3. can provide bigger lateral thrust, simple structure, the equipment process is convenient.

It is to be understood that the above-described embodiments are only a few, but not all, embodiments of the present invention. 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 invention.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments according to the present application. As used herein, the singular is intended to include the plural unless the context clearly dictates otherwise, and it should be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of features, steps, operations, devices, components, and/or combinations thereof.

It should be noted that the terms "first," "second," and the like in the description and claims of this application and in the drawings described above 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 described herein are capable of operation in sequences other than those illustrated or described herein.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.