CN218350662U - Optical element driving device, image pickup device, and mobile terminal - Google Patents

Abstract

The utility model provides an optical element drive arrangement, camera device and mobile terminal. Optical element drive arrangement includes shell and base, and the shell cover establish on the base and with the base between form the accommodation space, optical element drive arrangement still including setting up in the accommodation space: the bearing seat is movably arranged in the accommodating space; drive assembly, drive assembly sets up and is bearing between seat and the base, and drive assembly includes a plurality of flexible arms, and flexible arm has the expansion end, and the expansion end of flexible arm with bear a seat sliding connection, after drive assembly circular telegram, the expansion end of flexible arm slides and changes and bears the contact position of seat relative to the base to the messenger bears the seat and moves or relative Z axle skew along Z axle direction. The utility model provides an among the prior art camera device's the poor problem of drive arrangement performance.

Description

Optical element driving device, imaging device, and mobile terminal

Technical Field

The utility model relates to a camera device field particularly, relates to an optical element drive arrangement, camera device and mobile terminal.

Background

A video camera or a still camera usually employs a lens with adjustable focal length or automatic focusing, and the adjustment process is to change the position of the lens or an image sensor, and a driving motor is usually used for driving the lens and the image sensor to move. At present, the automatic focusing of a camera head of a handheld camera device, especially a mobile phone, is basically completed by using a Voice Coil Motor (VCM), which is a system composed of a Coil and a magnet. The coil after being electrified is subjected to electromagnetic force in a magnetic field, the winding carrier is driven to linearly move along the optical axis direction (namely a Z axis) of the lens under the action of the electromagnetic force, and the winding carrier finally stays at a position point when the resultant force of the electromagnetic force generated between the annular coil and the driving magnet and the elastic force of the upper spring and the lower spring reaches a phase equilibrium state.

Although the voice coil motor has the advantages of mature technology, low cost, low noise and the like, along with the increase of the requirement of the camera device on the camera shooting, the voice coil motor has the problems of magnetic interference, insufficient thrust and unstable structure and performance. For example: the double-shooting motor is developed and applied to various middle and high-end mobile phones, but certain puzzlement difficulty exists in the practical application process, particularly, a certain degree of magnetic interference phenomenon exists between two double-shooting motors, the normal performance of the effect of the double-shooting motors is influenced, the defect cannot be avoided by the voice coil motor, and meanwhile, various improvement schemes are easy to cause the complexity of the motor structure and the improvement of the assembly process difficulty; electric conduction and connection assembly among all parts in the voice coil motor are realized through modes such as welding, hot riveting, point gluing, coil circular telegram needs to be through last/lower spring intercommunication simultaneously, the route that leads to coil circular telegram is longer, because voice coil motor part number is more, need welding, hot riveting, point gluing department is more, when the cell-phone is in case receiving external force such as falling the striking, the motor is because external force vibrates and leads to inside welding point or point gluing department to pull phenomenon such as drop or spring deformation easily, the inside electric property of final motor and integrated configuration receive destruction, influence the performance of motor normal performance, bring unfavorable consequence for the shooting effect.

Therefore, the driving device of the imaging device in the prior art has the problem of poor service performance.

SUMMERY OF THE UTILITY MODEL

A primary object of the present invention is to provide an optical element driving device, an image capturing device, and a mobile terminal, which solve the problem of poor performance of the driving device of the image capturing device in the prior art.

In order to achieve the above object, according to an aspect of the present invention, there is provided an optical element driving device, including a housing and a base, the housing cover is disposed on the base and forms an accommodating space with the base, the optical element driving device further includes: the bearing seat is movably arranged in the accommodating space; drive assembly, drive assembly sets up and is bearing between seat and the base, and drive assembly includes a plurality of flexible arms, and flexible arm has the expansion end, and the expansion end of flexible arm with bear a seat sliding connection, after drive assembly circular telegram, the expansion end of flexible arm slides and changes and bears the contact position of seat relative to the base to the messenger bears the seat and moves or relative Z axle skew along Z axle direction.

Furthermore, each side of the bearing seat corresponds to at least one telescopic arm respectively, and when the driving assembly is electrified, the telescopic arms move along the corresponding side of the bearing seat.

Further, when the drive assembly is energized, the different telescopic arms move only in the X-axis and/or Y-axis direction.

Furthermore, one side of the bearing seat corresponding to the telescopic arm is provided with a plurality of abutting protrusions, each abutting protrusion is connected with the movable end of at least one telescopic arm in a sliding mode, each abutting protrusion corresponds to the telescopic arm and is provided with an abutting surface, and when the telescopic arm moves relative to the base, the movable end of the telescopic arm slides along the abutting surfaces.

Furthermore, in the moving direction of the movable end of the telescopic arm, the abutting surface is obliquely arranged relative to the body of the bearing seat, and an included angle which is larger than 0 degree and smaller than 90 degrees is formed between the abutting surface and the Z-axis direction.

Furthermore, the movable end of the telescopic arm is provided with a supporting surface parallel to the abutting surface, and at least one part of the supporting surface is in contact with the abutting surface so that the supporting surface slides along the abutting surface when the telescopic arm moves.

Further, the distance between the abutment surface and the body of the carrier seat gradually increases in a direction away from the corner of the body of the carrier seat.

Furthermore, the abutting surface is provided with a sliding groove extending along the movement direction of the telescopic arm, at least one part of the movable end of the telescopic arm extends into the sliding groove, and when the telescopic arm moves relative to the base, the part of the movable end of the telescopic arm extending into the sliding groove moves along the sliding groove.

Furthermore, each side of the bearing seat is correspondingly provided with an abutting projection, the abutting projections are correspondingly arranged at one ends of the corresponding sides, and the corner formed by the two adjacent sides is only provided with one abutting projection.

Furthermore, each side of the bearing seat is correspondingly provided with a telescopic arm, the extending direction of the telescopic arm is the same as that of the corresponding side, and different telescopic arms extend out towards different corners of the body of the bearing seat.

Further, the drive assembly includes: a telescoping spring having a plurality of telescoping arms; the FPC board is arranged on the base, and the telescopic spring is arranged between the FPC board and the bearing seat and is electrically connected with the FPC board; and when the SMA wires are electrified, the SMA wires contract and drive the telescopic arms to move relative to the base.

Furthermore, the driving assembly further comprises a plurality of clamping jaws, one end of the SMA wire is connected with the movable end of the telescopic arm through the clamping jaws, and the other end of the SMA wire is connected with the FPC board or the base through the clamping jaws.

Furthermore, the telescopic spring comprises a body part, the body part is arranged on the FPC board, the body part is annular, one end of the telescopic arm is connected with the outer periphery of the body part, and the other end of the telescopic arm is a movable end and can move relative to the body part.

Further, flexible arm is including linkage segment, compression section and the support section of connecting in order, and the one end that the compression section was kept away from to the linkage segment is connected with this somatic part, and the one end that the compression section was kept away from to the support section is the expansion end.

Further, the connecting section is tangent to the outer periphery of the body portion.

Furthermore, the movable end is provided with a mounting plane, a supporting bulge extending towards the bearing seat is arranged on the mounting plane, and the supporting bulge is connected with the bearing seat in a sliding manner.

Furthermore, one side of the supporting bulge facing the bearing seat is provided with a supporting surface or an arc surface.

Furthermore, every bight department of base has at least one orientation respectively and bears the reference column that the seat extends, and the reference column has the faying surface, bears the bight overlap joint of seat on the faying surface, and the faying surface has spacing arch, bears the seat have with spacing protruding complex spacing breach.

Furthermore, the optical element driving device further comprises a pressing sheet, wherein the pressing sheet is arranged on one side, far away from the driving assembly, of the bearing seat and connected with the top of the limiting protrusion, so that the bearing seat is provided with a reset force towards the driving assembly.

Furthermore, one side of the bearing seat, which is far away from the driving assembly, is provided with a plurality of mounting bulges; and/or the edge of one side of the bearing seat far away from the driving component is provided with a limiting wall.

According to another aspect of the present invention, there is provided an image pickup apparatus including the above-described optical element driving apparatus.

According to another aspect of the present invention, a mobile terminal is provided, which includes the above-mentioned camera device.

Use the technical scheme of the utility model, optical element drive arrangement in this application includes shell and base, the outer clamshell establish on the base and with the base between form the accommodation space, optical element drive arrangement still including set up the bearing seat and the drive assembly in the accommodation space. The bearing seat is movably arranged in the accommodating space; drive assembly sets up and bears between seat and the base, and drive assembly includes a plurality of flexible arms, and flexible arm has the expansion end, and the expansion end of flexible arm with bear a seat sliding connection, after drive assembly circular telegram, the expansion end of flexible arm slides and changes and bears the contact position of seat relative base to the base to make and bear the seat and follow Z axle direction motion or relative Z axle skew.

When the optical element driving device is used, an optical element in the camera module is installed on the bearing seat, and after the driving assembly is electrified, the movable end of the telescopic arm slides relative to the base and changes the contact position with the bearing seat, so that the bearing seat moves along the Z-axis direction or deflects relative to the Z-axis, and the automatic focusing function or the anti-shaking function of the optical element driving device can be realized through the movement of the telescopic arm. When the movement distances of the telescopic arms are the same, the telescopic arms can drive the bearing seat to move along the Z-axis direction and realize AF driving. And when the movement distances of the telescopic arms are different, the shift anti-shake function of the lens can be realized. That is, in the present application, the driving coil, the driving magnet portion, and the suspension anti-vibration portion of the conventional voice coil motor are replaced with the driving unit of the optical element driving device. In addition, since the present application does not require a spring or the like that cooperates with the driving magnet and the driving coil, the optical element driving device of the present application is simpler in structure than a conventional voice coil motor. Meanwhile, no magnet exists, so that the problem of magnetic interference inside or outside cannot be caused. In addition, the optical element driving device in the application has no magnetic circuit design problem, and the average thrust of the whole stroke is larger than that of an electromagnetic mode, so that the driving device is more efficient compared with the existing voice coil motor. And, there is not upper and lower spring design of voice coil motor, fall and test such as cylinder do not have spring deformation, nickel or foreign matter drop problem. Therefore, the optical element driving device in the application effectively solves the problem that the driving device of the image pickup device in the prior art is poor in service performance. In addition, in the application, when the movable end of the telescopic arm slides relative to the base and changes the contact position with the bearing seat, the telescopic arm moves in the XY axis direction, so that the movement requirement of the driving assembly on the Z axis direction is reduced, and the optical element driving device is lighter and thinner.

Drawings

The accompanying drawings, which form a part of the specification, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate exemplary embodiments of the invention and together with the description serve to explain the invention and do not constitute a limitation on the scope of the invention. In the drawings:

fig. 1 shows a schematic structural diagram of an optical element driving apparatus according to an embodiment of the present invention;

fig. 2 shows an exploded view of the optical element driving apparatus of fig. 1;

FIG. 3 is a schematic diagram illustrating a positional relationship among a base, a carrying base, and a pressing plate of an optical element driving apparatus according to an embodiment of the present application;

FIG. 4 is a schematic diagram of a driving assembly of an optical element driving apparatus according to an embodiment of the present application;

FIG. 5 is a schematic view of a carrier base of an optical element driving apparatus according to an embodiment of the present application;

FIG. 6 is a schematic view of a carrier base of an optical element driving apparatus according to another embodiment of the present application;

FIG. 7 is a schematic diagram showing a position relationship between the abutting surface and the movable end of the bearing seat in FIG. 5;

FIG. 8 is a schematic view showing a position relationship between the abutting surface and the movable end of the carrier in FIG. 6;

fig. 9 is a schematic view showing the movement of the carriage when the thread is energized differently in the optical element driving device of the present application;

fig. 10 is a schematic view showing the movement of the carriage when the optical element driving device of the present application is supplied with the same amount of electric power through the wires;

FIG. 11 is a schematic diagram illustrating the position of the extension spring and the pawl in one embodiment of the present application;

fig. 12 is an exploded view showing a part of the structure of the optical element driving device when the holder of the optical element driving device of the present application is used for carrying an image sensor.

Wherein the figures include the following reference numerals:

10. a housing; 20. a base; 21. a positioning column; 22. a lapping surface; 23. a limiting bulge; 30. a bearing seat; 31. an abutment projection; 311. an abutting surface; 3111. a chute; 32. mounting a boss; 33. a limiting wall; 40. a drive assembly; 41. a telescopic arm; 411. a movable end; 4111. a mounting plane; 4112. a support boss; 412. a connection section; 413. a compression section; 414. a support section; 42. a tension spring; 421. a body portion; 43. an FPC board; 44. SMA wire; 45. a jaw; 50. a limiting notch; 60. tabletting; 70. an image sensor.

Detailed Description

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

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 application, where the contrary is not intended, the use of directional words such as "upper, lower, top and bottom" is generally with respect to the orientation shown in the drawings, or with respect to the component itself in the vertical, perpendicular or gravitational direction; 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 problem that a driving device of an image pickup device in the prior art is poor in service performance, the application provides an optical element driving device, an image pickup device and a mobile terminal.

Note that the mobile terminal in the present application has an image pickup device, and the image pickup device in the present application has an optical element driving device described below.

It should be noted that the camera device in the present application can be applied to the field of miniature image photographing such as tablet, computer, and automotive electronics, besides the field of mobile phone.

As shown in fig. 1 to 11, the optical element driving device in the present application includes a housing 10 and a base 20, the housing 10 covers the base 20 and forms an accommodating space with the base 20, and the optical element driving device further includes a carrying seat 30 and a driving assembly 40 disposed in the accommodating space. The bearing seat 30 is movably arranged in the accommodating space; the driving assembly 40 is disposed between the carrier 30 and the base 20, the driving assembly 40 includes a plurality of telescopic arms 41, each telescopic arm 41 has a movable end 411, the movable ends 411 of the telescopic arms 41 are slidably connected to the carrier 30, and when the driving assembly 40 is powered, the movable ends 411 of the telescopic arms 41 slide relative to the base 20 and change the contact position with the carrier 30, so that the carrier 30 moves along the Z-axis direction or deflects relative to the Z-axis.

It should be noted that in the present application, when the drive assembly 40 is energized, the different telescopic arms 41 move only in the X-axis and/or Y-axis directions.

When the optical element driving apparatus of the present application is used, since the optical element driving apparatus has the bearing seat 30, the optical element (such as a lens, an image sensor, and an OIS anti-shake structure) in the camera module can be mounted on the bearing seat 30, the bearing seat 30 in this embodiment is a lens seat with a middle accommodating cavity, so as to facilitate the lens to be mounted in the lens seat, and since the movable end 411 of the telescopic arm 41 slides relative to the base 20 and changes the contact position with the lens seat after the driving assembly 40 is powered on, so as to move the lens seat along the Z-axis direction or incline relative to the Z-axis, the automatic focusing function or anti-shake function of the optical element driving apparatus can be realized through the movement of the telescopic arm 41. When the movement distances of the plurality of telescopic arms 41 are the same, the plurality of telescopic arms 41 can drive the lens mount to move in the Z-axis direction and realize AF drive. When the movement distances of the plurality of telescopic arms 41 are different, the shift anti-shake function of the lens can be realized. That is, in the present application, the driving coil, the driving magnet portion, and the suspension anti-shake portion of the conventional voice coil motor are replaced with the driving unit 40 of the lens driving apparatus. In addition, the lens driving device in the application is simpler in structure compared with the existing voice coil motor because structures such as a spring matched with the driving magnet and the driving coil are not needed any more. Meanwhile, no magnet exists, so that the problem of magnetic interference inside or outside is avoided. And, the camera lens drive arrangement in this application does not have the magnetic circuit design problem, and whole stroke dynamics average thrust is big than the electromagnetism mode, consequently compares more efficient with current voice coil motor. And, there is not the upper and lower spring design of voice coil motor, falls and test such as cylinder and does not have spring deformation, nickel or foreign matter dropout problem. Therefore, the lens driving device in the application effectively solves the problem that the driving device of the camera shooting device in the prior art is poor in service performance. Also, in the present application, when the movable end 411 of the telescopic arm 41 slides relative to the base 20 and changes the contact position with the lens holder, the telescopic arm 41 moves in the XY-axis direction, which reduces the movement requirement of the driving assembly 40 in the Z-axis direction, thereby making the lens driving apparatus thinner.

In another embodiment of the present application, as shown in fig. 12, when the carrier 30 is used to mount the image sensor 70, the side of the carrier 30 away from the driving assembly 40 has a plurality of mounting protrusions 32, and the edge of the side of the carrier 30 away from the driving assembly 40 has a limiting wall 33. That is, when the carrying seat 30 of the optical element driving device in the present application is used for carrying different elements, the structure thereof may be changed accordingly to adapt to the carried elements.

Specifically, each side of the carriage 30 corresponds to at least one telescopic arm 41, and when the driving assembly 40 is powered on, the telescopic arm 41 moves along the corresponding side of the carriage 30.

As shown in fig. 5 to 10, the carrier 30 has a plurality of abutting protrusions 31 on one side corresponding to the telescopic arms 41, each abutting protrusion 31 is slidably connected to the movable end 411 of at least one telescopic arm 41, the abutting protrusions 31 have abutting surfaces 311 corresponding to the telescopic arms 41, and when the telescopic arms 41 move relative to the base 20, the movable ends 411 of the telescopic arms 41 slide along the abutting surfaces 311.

In an embodiment of the present application, each abutting protrusion 31 corresponds to the movable end 411 of one telescopic arm 41, and when the positions where the movable ends 411 of different telescopic arms 41 contact with the corresponding abutting surfaces 311 are the same, the telescopic arms 41 can drive the carriage 30 to move along the Z-axis direction and realize AF driving. When the contact position between the movable end 411 of at least one telescopic arm 41 of the movable ends 411 of the telescopic arms 41 and the corresponding abutting surface 311 is different from the contact position between the movable end 411 of the other telescopic arm 41 and the corresponding abutting surface 311, the bearing seat 30 is deflected relative to the Z axis, so that the function of shifting the lens for preventing shake can be realized.

In the present application, the carrier 30 has a body and an abutment projection 31, and the abutment projection 31 is provided at a corner of the body on a side facing the drive assembly 40. Further, the distance between the abutment surface 311 of the abutment projection 31 and the body of the carrier 30 gradually increases in a direction away from the corner of the body of the carrier 30. Thus, when the telescopic arm 41 moves relative to the base 20, the end of the telescopic arm 41, which is in contact with the contact surface 311, slides relative to the contact surface 311 to change the position of the contact surface 311, so as to drive the carriage 30.

Meanwhile, for the body of the carrying seat 30 and the position of the abutting projection 31, each side of the body of the carrying seat 30 is correspondingly provided with one abutting projection 31 in the application, the abutting projection 31 is correspondingly arranged at one end of the corresponding side, and the corner formed by two adjacent sides is only provided with one abutting projection 31. Each side of the bearing seat 30 is correspondingly provided with a telescopic arm 41, the extending direction of the telescopic arm 41 is the same as the extending direction of the corresponding side, and different telescopic arms 41 extend out towards different corners of the body of the bearing seat 30.

As for the portion where the movable end 411 of the telescopic arm 41 contacts the abutment surface 311, in one specific embodiment of the present application, the movable end 411 of the telescopic arm 41 has a support surface parallel to the abutment surface 311, and at least a portion of the support surface contacts the abutment surface 311 so that the support surface slides along the abutment surface 311 when the telescopic arm 41 is operated. That is, in the present embodiment, the portion where the movable end 411 of the telescopic arm 41 contacts the abutment surface 311 is also a planar structure, so when the telescopic arm 41 is telescopic, the abutment surface 311 and the support surface contact each other and the support surface slides along the abutment surface 311. When the telescopic arm 41 is contracted, the supporting surface slides along the abutting surface 311, and the supporting surface is further away from the side of the carriage 30 away from the base 20, so that the driving of the carriage 30 by the driving assembly 40 is realized. When the areas of the contact surface 311 and the support surface are the same, when the driving unit 40 is not energized and the telescopic arm 41 is not extended or retracted, the contact surface 311 and the support surface can be completely attached to each other, and after the driving unit 40 is energized, the support surface can slide along the contact surface 311 along with the extension or retraction of the telescopic arm 41, and the contact area between the support surface and the contact surface 311 gradually decreases. Of course, in this embodiment, the area of the abutting surface 311 may be larger than that of the supporting surface, so that after the driving component 40 is powered on, the supporting surface can slide along the abutting surface 311 to contact the supporting surface with different positions of the abutting surface 311.

In another embodiment of the present application, as shown in fig. 6 and 8, the abutting surface 311 of the abutting protrusion 31 has a sliding groove 3111 extending along the moving direction of the telescopic arm 41, at least a portion of the movable end 411 of the telescopic arm 41 extends into the sliding groove 3111, and when the telescopic arm 41 moves relative to the base 20, the portion of the movable end 411 of the telescopic arm 41 extending into the sliding groove 3111 moves along the sliding groove 3111. That is, in the present embodiment, the portion of the movable end 411 of the telescopic arm 41 that contacts the contact surface 311 can be inserted into the slide groove 3111 of the contact surface 311, so that when the drive unit 40 is energized to extend and retract the telescopic arm 41, the portion of the telescopic arm 41 that is inserted into the slide groove 3111 can be moved in the longitudinal direction of the slide groove 3111. Therefore, the motion track of the telescopic arm 41 relative to the abutting surface 311 can be effectively limited, so that the contact part of the movable end 411 of the telescopic arm 41 and the abutting surface 311 cannot deflect relative to the abutting surface 311 in the telescopic process of the telescopic arm 41, the bearing seat 30 can move along the preset direction, and the running stability of the optical element driving device is further ensured. In this embodiment, the part of the telescopic arm 41 extending into the chute 3111 may be in the shape of a sphere, a hemisphere, a hexahedron, or the like.

In an embodiment of the present application, in the moving direction of the movable end 411 of the telescopic arm 41, the abutting surface 311 is disposed obliquely with respect to the body of the carriage 30, and an included angle between the abutting surface 311 and the Z-axis direction is greater than 0 degree and less than 90 degrees. Since the movable end 411 of the telescopic arm 41 can slide along the contact surface 311 when the telescopic arm 41 moves relative to the base 20, the contact surface 311 is inclined relative to the body of the carriage 30, and thus the carriage 30 can be surely lifted in the Z-axis direction when the portion of the movable end 411 in contact with the contact surface 311 slides along the contact surface 311.

In one embodiment of the present application, the base 20 and the carrying seat 30 each have four sides, and the number of the telescopic arms 41 is 4 in this embodiment, and each side of the carrying seat 30 is correspondingly provided with one telescopic arm 41. Of course, the structure of the base 20 and the carrier 30 of the optical element driving device in the present application is not limited to have four sides as in the present embodiment, and the number of the telescopic arms 41 can be adjusted according to the number of the sides of the base 20 and the carrier 30. Meanwhile, each side of the carrying seat 30 may also be correspondingly provided with a plurality of telescopic arms 41, so as to ensure the driving force of the driving assembly 40 on the carrying seat 30.

In the present application, the drive assembly 40 includes a telescoping spring 42, an FPC board 43, an SMA wire 44, and a plurality of jaws 45. The extension spring 42 has a plurality of extension arms 41, and the extension spring 42 further has a body 421, the body 421 is disposed on the FPC board 43, for better driving with the lens, the body 421 is disposed in a ring shape, one end of the extension arm 41 is connected to the outer periphery of the body 421, and the other end of the extension arm 41 is a movable end 411 and can move relative to the body 421. The FPC board 43 is arranged on the base 20, and the telescopic spring 42 is arranged between the FPC board 43 and the bearing seat 30 and is electrically connected with the FPC board 43; the number of the SMA wires 44 is multiple, each telescopic arm 41 corresponds to at least one SMA wire 44, one end of each SMA wire 44 is connected with the movable end 411 of each telescopic arm 41, the other end of each SMA wire 44 is connected with the FPC board 43 or the base 20, and after the SMA wires 44 are electrified, the SMA wires 44 contract and drive the telescopic arms 41 to move relative to the base 20. One end of the SMA wire 44 is connected to the movable end 411 of the telescopic arm 41 through the claw 45, and the other end of the SMA wire 44 is connected to the FPC board 43 or the chassis 20 through the claw 45.

It should be further noted that, in the present application, when the electric quantities applied to the different SMA wires 44 are the same, the contraction amounts of the different SMA wires 44 are the same, and at this time, the contraction degrees of the different telescopic arms 41 are the same, so that the moving distances of the movable ends 411 of the different telescopic arms 41 driving the bearing seat 30 are the same, thereby achieving the AF driving of the bearing seat 30. When different SMA wires 44 have different electric quantities, different SMA wires 44 have different contraction amounts, and different telescopic arms 41 have different contraction degrees, so that the movable ends 411 of different telescopic arms 41 drive the bearing seat 30 to have different movement distances, thereby achieving the anti-shake driving of the shift shaft of the bearing seat 30.

In a specific embodiment of the present application, one end of the SMA wire 44 is connected to the FPC board 43 through the claw 45, the other end of the SMA wire 44 is connected to the movable end 411 of the telescopic arm 41 through the claw 45, and the SMA wire 44 can be electrically connected to the FPC board 43 and the telescopic arm 41 through the claw 45, so that after the FPC board 43 is powered on, the SMA wire 44 is powered on and contracted, thereby driving the movable end 411 to squeeze the telescopic arm 41 and move along the base 20, thereby changing the contact position of the movable end 411 and the abutting protrusion 31 of the bearing seat 30, and further driving the bearing seat 30 to move. In the present embodiment, the FPC board 43 is fixedly connected to the chassis 20, the body 421 of the extension spring 42 is fixedly disposed on the FPC board 43, and the extension arm 41 of the extension spring 42 is movable relative to the body 421 of the extension spring 42. That is, one of the two claws 45 connected to both ends of the SMA wire 44 is provided on the FPC board 43, and the other claw 45 is provided on the movable end 411 of the telescopic arm 41.

Of course, in the present application, one end of the SMA wire 44 may also be connected to the base 20 through the pawl 45, and the other end of the SMA wire 44 is connected to the movable end 411 of the telescopic arm 41 through the pawl 45. That is, one of the two jaws 45 connected to the SMA wire 44 is provided on the base 20, and the other jaw 45 is provided on the movable end 411 of the telescopic arm 41. It should be noted that although the claws 45 can be provided on the base 20, it is necessary to ensure that the SMA wires 44 can be electrically connected to the FPC board 43 through the claws 45.

In an embodiment of the present application, the telescopic arm 41 includes a connection section 412, a compression section 413 and a support section 414 connected in sequence, wherein an end of the connection section 412 away from the compression section 413 is connected to the body 421, the compression section 413 may be a bow spring, a coil spring, a serpentine spring, etc. formed by bending, and an end of the support section 414 away from the compression section 413 is a movable end 411. In the present embodiment, the connecting portion 412 is tangent to the outer edge of the body portion 421 of the extension spring 42. Also, when the SMA wire 44 is electrically contracted, the compression section 413 is pressed, and the direction in which the compression section 413 is pressed is the length direction of the connection section 412.

Optionally, the movable end 411 has a mounting plane 4111, and a supporting protrusion 4112 extending toward the carrier 30 is disposed on the mounting plane 4111, and the supporting protrusion 4112 is slidably connected to the carrier 30. And, one side of the supporting protrusion 4112 facing the carrying seat 30 has a supporting surface or an arc surface. In one embodiment of the present application, the claw 45 connected to the movable end 411 of the telescopic arm 41 is bent and formed by the mounting plane 4111.

Preferably, the telescopic arm 41 and the body 421 of the telescopic spring 42 are integrally formed.

In another embodiment of the present application, the driving assembly 40 may not have the telescopic spring 42 but only have a plurality of telescopic arms 41, and one end of the telescopic arm 41 is a movable end 411, and the other end of the telescopic arm 41 is fixedly disposed on the FPC board 43.

Optionally, each corner of the base 20 has at least one positioning pillar 21 extending toward the load-bearing seat 30, the positioning pillar 21 has an overlapping surface 22, the corner of the load-bearing seat 30 overlaps the overlapping surface 22, and the overlapping surface 22 has a position-limiting protrusion 23, and the load-bearing seat 30 has a position-limiting notch 50 cooperating with the position-limiting protrusion 23. The arrangement can effectively limit the movement of the bearing seat 30, thereby ensuring the service performance of the optical element driving device.

Specifically, the optical element driving apparatus further includes a pressing sheet 60, and the pressing sheet 60 is disposed on a side of the carrier 30 away from the driving assembly 40 and connected to a top of the limiting protrusion 23 to provide a restoring force to the carrier 30 toward the driving assembly 40. It should be noted that, in the present application, when the SMA wire 44 is in the non-energized state, a pre-tightening force may be provided to the bearing seat 30 through the pressing sheet 60, so that a balancing force during the movement of the bearing seat 30 can be provided through the pressing sheet 60 after the SMA wire 44 is energized, and a resetting force is provided to the bearing seat 30 after the SMA wire 44 is de-energized.

In one embodiment of the present application, the sheeting 60 includes a press portion and a connecting portion. The extrusion part is annular and is abutted with the bearing seat 30; the connecting parts are in one-to-one correspondence with the positioning columns 21, one end of each connecting part is connected with the extrusion part, and the other end of each connecting part is connected with the limiting bulge 23 of each positioning column 21.

Optionally, the housing 10 is made of a plastic material. Of course, other structures in the present application that do not require energization in the optical element driving apparatus may also be made of plastic materials.

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

1. the structure is simple, the assembly is easy, the circuit routing is simple, and the circuit is stable.

2. The absence of magnets does not create problems of magnetic interference, either internal or external.

3. The design problem of a magnetic circuit is avoided, and the average thrust of the whole stroke is larger than that of a magnetoelectric mode and more efficient than that of the magnetoelectric mode.

4. The voice coil motor has no upper spring and lower spring design, and the problems of spring deformation and nickel or foreign matter falling do not occur when the voice coil motor falls and is tested by a roller and the like.

5. The motor housing can be made of plastic, which contributes to the gain of the mobile terminal antenna db.

6. The motor with different appearance structures can be manufactured.

7. The size and area of the finished motor products with the same lens diameter can be smaller than those of the finished motor products with the same lens diameter in a magnetoelectric mode.

It is obvious that the above described embodiments are only some of the embodiments of the present invention, and not all of them. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts 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 accompanying drawings 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.

Claims (22)

1. An optical element driving device, 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 optical element driving device further comprises:

the bearing seat (30), the bearing seat (30) is movably arranged in the containing space;

drive assembly (40), drive assembly (40) set up bear seat (30) with between base (20), drive assembly (40) include a plurality of flexible arms (41), flexible arm (41) have loose end (411), the loose end (411) of flexible arm (41) with bear seat (30) sliding connection, work as drive assembly (40) circular telegram back, the loose end (411) of flexible arm (41) is relative base (20) slide and change with bear the contact position of seat (30), so that bear seat (30) along the motion of Z axle direction or relative Z axle skew.

2. Optical element driving device according to claim 1, wherein each side of the carrying seat (30) corresponds to at least one telescopic arm (41), and when the driving assembly (40) is energized, the telescopic arms (41) move along the corresponding side of the carrying seat (30).

3. Optical element driving device according to claim 1, characterized in that the different telescopic arms (41) are only moved in the X-axis and/or Y-axis direction when the driving assembly (40) is energized.

4. The optical element driving device according to claim 1, wherein the carrier (30) has a plurality of abutting protrusions (31) on a side corresponding to the telescopic arms (41), each abutting protrusion (31) is slidably connected to a movable end (411) of at least one of the telescopic arms (41), the abutting protrusions (31) have abutting surfaces (311) corresponding to the telescopic arms (41), and the movable ends (411) of the telescopic arms (41) slide along the abutting surfaces (311) when the telescopic arms (41) move relative to the base (20).

5. The optical element driving device according to claim 4, wherein the abutting surface (311) is disposed obliquely with respect to the body of the carriage (30) in the moving direction of the movable end (411) of the telescopic arm (41), and the abutting surface (311) has an angle greater than 0 degree and less than 90 degrees with respect to the Z-axis direction.

6. An optical element driving device according to claim 5, wherein the movable end (411) of the telescopic arm (41) has a support surface parallel to the abutment surface (311), at least a portion of said support surface being in contact with the abutment surface (311) so as to slide along the abutment surface (311) when the telescopic arm (41) is actuated.

7. An optical element driving device according to claim 5, wherein the distance between the abutment surface (311) and the body of the carrier (30) gradually increases in a direction away from a corner of the body of the carrier (30).

8. The optical element driving device according to claim 4, wherein the contact surface (311) has a sliding groove (3111) extending in a moving direction of the telescopic arm (41), at least a portion of the movable end (411) of the telescopic arm (41) protrudes into the sliding groove (3111), and a portion of the movable end (411) of the telescopic arm (41) protruding into the sliding groove (3111) moves along the sliding groove (3111) when the telescopic arm (41) moves relative to the base (20).

9. An optical element driving device according to claim 4, wherein each side of the carrier (30) is provided with one of the abutting protrusions (31), the abutting protrusions (31) are provided at one end of the corresponding side, and the corner formed by two adjacent sides is provided with only one abutting protrusion (31).

10. Optical element driving device according to claim 1, wherein each side of the carrying seat (30) is provided with one telescopic arm (41), the extending direction of the telescopic arms (41) is the same as the extending direction of the corresponding side, and different telescopic arms (41) extend towards different corners of the body of the carrying seat (30).

11. An optical element driving device according to claim 1, wherein the driving assembly (40) comprises:

a telescopic spring (42), said telescopic spring (42) having a plurality of said telescopic arms (41);

the FPC board (43), the FPC board (43) is arranged on the base (20), and the telescopic spring (42) is arranged between the FPC board (43) and the bearing seat (30) and is electrically connected with the FPC board (43);

SMA silk thread (44), SMA silk thread (44) are a plurality of, every flexible arm (41) respectively with at least one SMA silk thread (44) correspond, the one end of SMA silk thread (44) with the expansion end (411) of flexible arm (41) are connected, the other end of SMA silk thread (44) with FPC board (43) or base (20) are connected, work as after SMA silk thread (44) circular telegram, SMA silk thread (44) shrink and drive flexible arm (41) are relative base (20) motion.

12. Optical element driving device according to claim 11, wherein the driving assembly (40) further comprises a plurality of claws (45), one end of the SMA wire (44) being connected to the movable end (411) of the telescopic arm (41) by means of the claws (45), the other end of the SMA wire (44) being connected to the FPC board (43) or the chassis (20) by means of the claws (45).

13. The optical element driving device according to claim 11, wherein the extension spring (42) includes a body portion (421), the body portion (421) is provided on the FPC board (43), the body portion (421) is ring-shaped, and one end of the extension arm (41) is connected to an outer peripheral edge of the body portion (421), and the other end of the extension arm (41) is a movable end (411) and is movable relative to the body portion (421).

14. An optical element driving device according to claim 13, wherein the telescopic arm (41) comprises a connecting section (412), a compressing section (413) and a supporting section (414) which are connected in sequence, wherein one end of the connecting section (412) far away from the compressing section (413) is connected with the main body portion (421), and one end of the supporting section (414) far away from the compressing section (413) is a movable end (411).

15. An optical element driving device according to claim 14, wherein said connecting section (412) is tangential to an outer circumference of said body portion (421).

16. An optical element driving device according to any one of claims 1 to 15, wherein the movable end (411) has a mounting plane (4111), a supporting protrusion (4112) extending towards the carrier (30) is arranged on the mounting plane (4111), and the supporting protrusion (4112) is slidably connected with the carrier (30).

17. An optical element driving device according to claim 16, wherein a side of the supporting protrusion (4112) facing the carrier seat (30) has a supporting surface or an arc surface.

18. The optical element driving device as claimed in any one of claims 1 to 15, wherein the base (20) has at least one positioning post (21) extending toward the bearing seat (30) at each corner, the positioning post (21) has an overlapping surface (22), the corner of the bearing seat (30) overlaps the overlapping surface (22), and the overlapping surface (22) has a limit protrusion (23), and the bearing seat (30) has a limit notch (50) cooperating with the limit protrusion (23).

19. The optical element driving device according to claim 18, further comprising a pressing piece (60), wherein the pressing piece (60) is disposed on a side of the carrying seat (30) away from the driving assembly (40) and connected with a top of the limiting protrusion (23) to provide a restoring force to the carrying seat (30) toward the driving assembly (40).

20. The optical element driving device according to any one of claims 1 to 15,

the side, far away from the driving assembly (40), of the bearing seat (30) is provided with a plurality of mounting projections (32); and/or

The edge of one side of the bearing seat (30) far away from the driving component (40) is provided with a limiting wall (33).

21. An image pickup apparatus comprising the optical element driving apparatus according to any one of claims 1 to 20.

22. A mobile terminal characterized in that it comprises the camera device according to claim 21.

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