JP4438098B2 - Manufacturing method of lens driving device - Google Patents

Description

  The present invention relates to a method of manufacturing a lens driving device used in a relatively small camera such as a camera-equipped mobile phone camera.

  In many cases, a mobile phone equipped with a camera holds a mobile phone with one hand and shoots the subject's own face or other close-up subject. For this reason, many photographic lens systems used in this type of camera have a close-up photographing function. In the case of a photographing lens system having such a close-up photographing function, the lens position when performing normal photographing differs from the lens position when performing close-up photographing, that is, macro photographing. That is, the lens position during close-up photography is a position that is closer to the subject side by a slightly fixed distance than the lens position during normal photography. For this reason, this type of photographic lens system includes a drive mechanism for moving the lens position between the normal photographic position and the macro photographic position, and drives the drive mechanism by switching the switch. The lens moves between shooting positions.

  On the other hand, in a small camera, a lens driving device of a type that moves the lens by directly using electromagnetic force for driving the lens is mounted for reasons such as downsizing and weight reduction of the device (for example, Patent Document 1). , See Patent Document 2).

JP 2000-187862 A JP-A-10-150759

  A conventional small camera, particularly a camera part of a mobile phone, has a very small diameter of about 10 mm, and is difficult to handle when electromagnetic parts such as a yoke or a coil are inserted and fixed, and the position within the case is likely to shift. It has become. If a position shift occurs in the ultra-small electromagnetic component, the drive mechanism for moving the lens position becomes defective, and in the worst case, the lens position cannot be switched.

  In addition, in conventional cellular phone lens driving devices, an adhesive is used when fixing ultra-compact parts to a case body, etc., so the parts are misaligned before the adhesive is fixed, and the position shifts. It has been fixed in a state. Furthermore, it is necessary to put a dispenser for applying an adhesive in a narrow part of the case body to perform the application work, and the workability is extremely deteriorated.

  In addition, an ultraviolet curable adhesive is usually used as an adhesive for adhesive fixing, but it is difficult to apply in a narrow range, and it is difficult for the adhesive to penetrate, and parts to which ultraviolet rays are to be bonded There is a problem that it is difficult to wrap around to the back side. As a result, workability is inferior, leading to an increase in cost, and fixing of parts becomes unstable, leading to an increase in quality defects.

  The present invention has been made in order to solve the above-described problems, and an object of the present invention is to provide a lens driving device that can prevent positional displacement of components, particularly micro components, and can improve workability. Another object of the present invention is to provide a method of manufacturing a lens driving device that can shorten the time of the manufacturing process.

  To achieve the above object, the present invention provides the following:

  (1) In a method for manufacturing a lens driving device, comprising: a lens holder provided with a lens; and a fixed body that moves the lens holder in the optical axis direction of the lens and holds the lens holder. The lens holder is configured by a case body that accommodates the lens holder therein, and the case body is configured to be divided into at least two parts, each of which is a case half, and the lens holder is provided in the one case half The one case half so as to be brought into contact with a contact portion as a movement limit, and a spacer is sandwiched between the lens holder and the contact portion as a movement limit provided in the other case half And the other case half, and after that, the spacer is pulled out.

  According to the present invention, the method for manufacturing a lens driving device according to the present invention is configured such that the case body of the lens driving device can be divided into at least two parts, each of which is a case half, and the lens holder is one case half. A contact portion as a movement limit provided and a spacer between the contact portion as a movement limit provided in the other case half and the lens holder (for example, one After the case half and the other case half are relatively moved in the optical axis direction), one case half and the other case half are fixed, and then the spacer is extracted.

  In this invention, since the lens driving device in which the moving distance of the moving body is reliably set at a constant interval can be obtained by arranging and removing the spacer after the spacer is arranged, the adjustment work of the gap becomes unnecessary, and the manufacturing process time Is shortened. In addition, since a lens driving device can be obtained in which the moving distance of the moving body is set at a certain interval, the lens driving device can be purchased and easily produced by a person who manufactures a portable device with a camera. At the same time, a portable device with a camera of stable quality is manufactured.

  (2) Manufacturing of a lens driving device, wherein at least one through-hole is formed in the spacer, a drawing member is passed through the through-hole, and the spacer is drawn by pulling the drawing member. Method.

  According to the present invention, at least one through-hole is formed in the spacer described above, and the extraction member is passed through the through-hole such as a thread, and the spacer is extracted by pulling the extraction member. Therefore, workability can be improved, and as a result, manufacturing time can be shortened.

  Here, “pulling the extraction member” means that, for example, when the extraction member is a thread, it is considered to pull a thread that is passed through the through hole and has a knot formed at the tip. It is also conceivable to form two through holes, pass one thread through these two through holes, and pull both ends of the thread. In addition, the mode of pulling the extraction member is not limited.

  (3) A protrusion is provided on the outer periphery of the spacer, a notch recess is provided at the edge of the lens opening formed in the other case half, and the protrusion is passed through the notch recess. A manufacturing method of a lens driving device, wherein the spacer is extracted.

  According to the present invention, the spacer is extracted by passing the protrusion provided on the outer periphery of the spacer described above through the notch recess provided on the edge of the lens opening formed on the other case half described above. Therefore, even a spacer that does not have flexibility can be easily extracted, workability can be improved, and manufacturing time can be shortened.

  (4) Before sandwiching the spacer between the lens holder and the contact portion as the movement limit provided on the other case half, the spacer is previously adhered to the contact portion with an adhesive material. A method for manufacturing a lens driving device.

  Before sandwiching the spacer between the above-mentioned contact portion as the movement limit provided in the other half of the case and the above-described lens holder, the spacer is previously adhered to the contact portion by an adhesive material. Therefore, workability can be improved.

  The lens driving device manufactured by the manufacturing method of the lens driving device according to the present invention will be supplementarily described. First, in a lens driving device having a lens holder provided with a lens and a fixed body for moving the lens holder in the optical axis direction of the lens and holding the lens holder, the lens holder includes a first magnetic means. The fixed body includes a first magnetic means and a second magnetic means disposed so that the lens holder can be moved by a magnetic attraction force or a magnetic repulsive force. The fixed body accommodates the lens holder therein. The second magnetic means is fixed to the fixed body with an adhesive.

  Thereby, since the 2nd magnetic means is being fixed to the fixed body with the adhesive, the position shift of the 2nd magnetic means can be prevented and workability | operativity is improved compared with adhesive use. Further, the operation of the lens holder that operates by the magnetic action with the second magnetic means is also stabilized.

  Further, in a lens driving device having a lens holder provided with a lens and a fixed body for moving the lens holder in the optical axis direction of the lens and holding the lens holder, the lens holder has a first magnetic means. The fixed body includes a first magnetic means and a second magnetic means disposed so that the lens holder can be moved by a magnetic attraction force or a magnetic repulsive force. The fixed body accommodates the lens holder therein. The second magnetic means includes a magnetic body and a coil, and both of them are fixed with an adhesive.

  Thereby, since the magnetic body and coil used as the 2nd magnetic means are being fixed with the adhesive, position shift with a magnetic body and a coil can be prevented, and workability | operativity improves compared with fixation of an adhesive agent.

  Further, it is preferable that the lens holder has a surface facing the second magnetic means disposed in a direction orthogonal to the optical axis direction, and moves in the optical axis direction in proximity to the second magnetic means. If comprised in this way, even if a moving body and a 2nd magnetic means are arrange | positioned closely, the space | interval of a moving body and a 2nd magnetic means can be hold | maintained correctly. Further, by not using the adhesive, the phenomenon that the adhesive protrudes into the interval between them does not occur, and the quality defect can be drastically reduced.

  Moreover, it is preferable that the second magnetic means is fitted into a ring-shaped groove having a U-shaped cross section provided in the fixed body. When this configuration is employed, the second magnetic means can be accurately positioned. Moreover, in the case of an adhesive, it is difficult to apply and harden it, but such a problem does not occur because an adhesive is used.

  According to the present invention, it is possible to obtain a lens driving device that can prevent misalignment of components, particularly micro components, and can improve workability. In addition, according to another invention, it is possible to obtain a method of manufacturing a lens driving device that can shorten the time of the manufacturing process.

  Hereinafter, embodiments of a lens driving device according to the present invention will be described with reference to the drawings. In addition, the manufacturing method of a lens drive device and the portable apparatus with a camera are also demonstrated. Each embodiment has a configuration suitable for mounting as a camera portion of a mobile device such as a mobile phone, but may be mounted on another mobile device such as a PDA (Personal Degital Assistance).

FIG. 1 is a cross-sectional view of a lens driving device 1 according to a first embodiment of the present invention. The lens driving device 1 houses a lens holder 10 that holds a lens 14, a driving unit that moves the lens holder 10 along the direction of the optical axis 11 of the lens 14, and the lens holder 10 and the driving unit. It is mainly comprised from the case body 24 used as the fixing body which fixes a part of means. A lens 14 is provided inside the lens holder 10. The lens 14 is a photographic lens of a camera and is configured by combining a plurality of lenses. The upper side of FIG. 1 is the subject side lens 14a, and the lower side is the camera body side lens 14b. In the lens driving device 1, the lens 14 and the lens holder 10 that holds the lens 14 are formed of different members, but both may be integrally formed of the same member.

  The outer periphery of the lens holder 10 composed of the lens barrel 12 and the like has a large diameter on the front side and a small diameter on the rear side, and a step is formed at the boundary. The small-diameter portion on the rear side is fitted with a ring-shaped drive magnet 16 serving as a first magnetic means, and the drive magnet 16 is integrated with the lens holder 10 in contact with the stepped portion described above. It is fixed to. Inside the lens barrel 12, a spacing member 14 c is placed between the subject side lens 14 a and the camera body side lens 14 b, and the position fixing member 14 d presses the lens 14 so that the rear side of the lens barrel 12. It is fixed to the inner peripheral surface.

  A circular incident window 18 for taking reflected light from the subject into the lens 14 is formed at the front end of the lens holder 10, that is, the end on the subject side. Although an openable / closable barrier for holding the lens is provided in front of the entrance window 18, the illustration is omitted.

The lens holder 10 is accommodated in the case body 24. The case body 24 includes a rear first case divided body 26 that is also a cylindrical first fixing member and a front second case divided body 42 that is also a second fixing member. First, second casing divided body 26, 42 serves as a casing halves, as shown in FIG. 1, another cylindrical projecting portion 26a, 42a is joined to engage. The 1st, 2nd case division bodies 26 and 42 can also be made into the same shape. If they have the same shape, the parts can be shared and the manufacturing cost can be reduced. In the first embodiment, the case body 24 is divided into two, but it may be divided into three or more. A portion excluding the filter 43, the image sensor 44, the circuit board 45, the rear end member 46, and the image sensor case 47, that is, the case body 24 and the member incorporated in the case body 24 are referred to as a case body portion.

The first and second power supply lines 72 and 74 that are the power supply members of the first and second drive coils 28 and 30 are formed by dividing the case body 24 into the first and second case divided bodies 26 and 42. It is pulled out to the outside of the case body 24 from the notches 62 and 64 (see FIG. 3 ) serving as power feeding member passing portions opened to the joint surfaces 26b and 42b (dividing surfaces of the case body 24) (see FIG. 2 ). The first and second feed lines 72 and 74 drawn out of the case body 24 are connected to a power source (not shown). In addition, it is preferable that the dividing surfaces 26 b and 42 b of the case body 24 are substantially at the center of the linear movement range of the lens holder 10. Further, in the first embodiment, the notches 62 and 64 are set at positions shifted in the circumferential direction . Therefore, when assembled, as shown in FIG. However, the overhanging portion 26a of the first case divided body 26 is closed.

The outer periphery of the rear end portion of the lens holder 10 is fitted to the inner periphery of the rear end portion of the first case divided body 26 so that the lens 14 can move in the direction of the optical axis 11. The movement limit of the lens holder 10 to the rear side, that is, the camera body side is a position where the lens holder 10 abuts on a protruding edge 27 formed inwardly at the rear end of the first case divided body 26. FIG. 1 shows a state in which the lens holder 10 has moved to the rearmost side. This protruding edge 27 becomes one contact portion.

The drive magnet 16 that operates integrally with the lens holder 10 is a front side of the inner periphery of the rear end portion of the first case divided body 26 and has a larger inner diameter than the inner periphery of the rear end portion. It is installed so as to face the inner circumference with a slight gap. The drive magnet 16 has a ring shape, and as shown in FIG. 4 , the portion surrounding the central hole is magnetized to the N pole, and the entire outer peripheral portion is magnetized to the S pole. Note that this magnetization relationship may be such that NS is reversed. The drive magnet 16 is housed so as to be movable relative to the first case divided body 26 in the direction of the optical axis 11.

  A first drive coil 28 wound in a ring shape so as to face the drive magnet 16 is disposed on the inner periphery of the first case divided body 26 on the rear side of the drive magnet 16. The first drive coil The second drive coil 30 is arranged so that the drive magnet 16 is sandwiched with respect to 28. The first and second drive coils 28 and 30 have first and second feeder lines 72 and 74, respectively.

  A ring-shaped first magnetic body 32 is arranged on the rear side of the first drive coil 28. In the second case divided body 42, a second drive coil 30 wound in a ring shape and a ring-shaped second magnetic body 34 are held and fixed so as to overlap the second drive coil 30. Therefore, the first magnetic body 32 and the second magnetic body 34 are arranged outside the first drive coil 28 and the second drive coil 30 that are aligned in the direction of the optical axis 11 with the drive magnet 16 in between, respectively. Yes. The first drive coil 28 and the first magnetic body 32 are fitted in by being dropped into a ring-shaped groove 26c having a U-shaped cross section. Further, the second drive coil 30 and the second magnetic body 34 are similarly fitted in the U-shaped section 42c by being dropped into the ring-shaped groove 42c.

  The first and second magnetic bodies 32 and 34 are made of a washer-like ferromagnetic body, for example, a steel plate. The magnetic flux emitted from the drive magnet 16 passes through the first drive coil 28 and the first magnetic body 32 from the center side to the outer peripheral side and returns to the drive magnet 16. Further, the magnetic flux from the driving magnet 16 passes through the second magnetic body 34 and the second driving coil 30 from the center side to the outer peripheral side and reaches the driving magnet 16, and these members constitute a magnetic circuit. Has been. Therefore, the first and second drive coils 28 and 30 are located in the magnetic field formed by the drive magnet 16.

  The distance between the opposing surfaces of the first and second drive coils 28 and 30 is larger than the thickness of the drive magnet 16 in the direction of the optical axis 11, and the distance between the drive magnet 16 and the first drive coil 28 or the second drive coil 30. There is a gap in the direction of the optical axis 11, and the drive magnet 16 and thus the lens holder 10 integrated with the drive magnet 16 can move in the direction of the optical axis 11 within the range of the gap.

In the state shown in FIG. 1 , the magnetic attractive force generated between the drive magnet 16 and the first magnetic body 32 even when the drive magnet 16 moves rearward together with the lens holder 10 and the drive coils 28 and 30 are not energized. Is held at the normal shooting position. At this time, as shown in FIG. 1 , a slight gap is generated between the first drive coil 28 and the drive magnet 16. This is because when one of the first drive coil 28 and the drive magnet 16 collides, either one or both are damaged, and the collision is prevented.

In the state shown in FIG. 1, when a predetermined macro changeover switch (not shown) is operated, at least one of the first and second drive coils 28, 30 is energized in a predetermined direction. Depending on the direction of the magnetic field, an electromagnetic force that pushes the drive magnet 16 forward acts according to Fleming's left-hand rule, and the lens holder 10 advances forward together with the drive magnet 16. This advance amount is within the above-described gap generated between the drive magnet 16 and the first and second drive coils 28 and 30. The lens 14 moves forward together with the lens holder 10 to become a macro photographing position. Note that Fleming's left-hand rule shows the relationship of forces acting on an object that is carrying a line current when a line current flows in the magnetic field. In this embodiment, the first, Since the second drive coils 28 and 30 are both fixed, a force acts on the drive magnet 16 as a reaction.

  When the lens holder 10 moves forward, the lens holder 10 collides with the protrusion 36 of the second case divided body 42, thereby preventing the forward movement. At this time, the projection 36 becomes the other contact portion at the macro photographing position. The protrusion 36 preferably has a shape protruding by three points rather than a circumferential shape for the purpose of improving accuracy. The lens 14 at the macro photographing position is held by the magnetic attractive force generated between the drive magnet 16 and the second magnetic body 34 even when the first and second drive coils 28 and 30 are not energized. Also at this time, a slight gap is generated between the second drive coil 30 and the drive magnet 16. This is also for preventing the second drive coil 30 and the drive magnet 16 from colliding and damaging them.

  The electromagnetic force generated during the forward movement is generated in such a direction that the drive magnet 16 is moved forward when the first drive coil 28 is energized, and the drive magnet 16 is moved forward when the second drive coil 30 is energized. Generate in the direction to move to. Both the first and second drive coils 28 and 30 may be energized simultaneously, or one of them may be energized.

To switch from the macro shooting position to the normal shooting position, the changeover switch is switched to the normal shooting position. By this switching, at least one of the first and second drive coils 28 and 30 is energized in the opposite direction, and the drive magnet 16 is moved backward by Fleming's left hand rule according to the direction of this current and the direction of the magnetic field by the drive magnet 16. The electromagnetic force in the direction of pulling back is activated, and the lens holder 10 moves backward together with the drive magnet 16 to reach the normal photographing position shown in FIG .

  On the rear side along the optical axis 11 of the lens driving device 1, an image sensor case 47 that houses the filter 43, the image sensor 44, the circuit board 45, and the like is disposed. The filter 43 is for cutting light of a predetermined wavelength corresponding to the detection wavelength of the image sensor 44. The image sensor 44 is composed of a complementary metal oxide semiconductor (CMOS), and sends the detection signal to the circuit board 45. An image signal serving as a detection signal is sent via a circuit board 45 to a control unit configured by a microcomputer (not shown). In addition to the CMOS, a CCD, a VMIS, or the like can be used as the image sensor 44. Further, the lens driving device 1 is incorporated as a mechanism of the camera portion of the camera-equipped mobile phone, but may be incorporated into another portable device.

Next, a manufacturing method of the lens driving device 1 according to the first embodiment will be described with reference to FIG .

First, the first magnetic body 32 and the first drive coil 28 are sequentially arranged on the first case divided body 26. As shown in FIG. 3 , the first magnetic body 32 has adhesive sheets 33, 33 serving as adhesives attached to both sides thereof. The pressure-sensitive adhesive sheet 33 is formed by punching out a PET (polyethylene terephthalate) base sheet coated with an acrylic pressure-sensitive adhesive at the center into the shape of the first magnetic body 32 or an approximate shape. Moreover, the thickness of the adhesive sheet 33 is 10-30 micrometers.

The adhesive sheet 33 is attached to the first magnetic body 32 as shown in FIG . That is, the adhesive sheet 33 with release paper is first placed with the adhesive surface facing upward on the jig 51 whose center 51a is a cone or a truncated cone. Next, the first magnetic body 32 is attached on the adhesive surface of the adhesive sheet 33. Thereafter, the adhesive surface of another adhesive sheet 33 with release paper is placed on the first magnetic body 32 and pasted. In this way, the adhesive sheet 33 is attached to both sides of the first magnetic body 32. Both surfaces of this integrated object are non-adhesive surfaces due to the presence of release paper.

A thin sheet is affixed to the non-adhesive surface, and it is necessary to peel off the sheet to expose the adhesive layer. In order to facilitate this peeling work, a notch 32b is provided on the outer periphery of the first magnetic body 32 as shown in FIG . The first magnetic body 32 is provided with a slit 32c for guiding the first coil of the first drive coil 28 outward. The first power supply line 72 of the first drive coil 28 passes through a notch 62 as a power supply member passage portion of the first case divided body 26 and is drawn out of the case body 24.

  Similarly, the second magnetic body 34 and the second drive coil 30 are also sequentially arranged on the second case divided body 42. Adhesive sheets 35 are also attached to both sides of the second magnetic body 34. The attaching method and the shape of the second magnetic body 34 are the same as those of the first magnetic body 32 described above. Further, the second power supply line 74 of the second drive coil 30 is pulled out of the case body 24 through the notch 64 of the second case divided body 42. Thereafter, the lens holder 10 is accommodated in the first and second case segments 26 and 42 so that the lens holder 10 having the drive magnet 16 fixed in advance is sandwiched between the first and second case segments 26 and 42. To do. And the 1st, 2nd case division bodies 26 and 42 are joined and integrated.

The integration of the first and second case segments 26 and 42 is provisional at this point. If integrated case body 24 (the lens holder 10 is already built) it is fixed with an adhesive 48 or the like to the image sensor casing 47 as shown in FIG. This fixing is performed after adjusting the distance between the image sensor 44 and the lens 14. That is, when the lens 14 is in the normal photographing position, the case body 24 (first case division body 26) is fixed to the image sensor case 47 at the optimum position by adjusting the image so as to be appropriate. Thereafter, the second case segment 42 is moved relative to the first case segment 26 so that the macro image is optimal when the lens 14 is set to the macro photographing position. And the 2nd case division body 42 is finally fixed with an adhesive etc. in the position which obtains an optimal macro image, and the 1st, 2nd case division bodies 26 and 42 are integrated completely.

  Further, the notches 62 and 64 of the first and second case division bodies 26 and 42 are displaced in the circumferential direction in order to suppress the entry of dust into the case body 24, but the first and second cases The notches 62 and 64 opened to the dividing surfaces of the divided bodies 26 and 42 may communicate with each other.

  Next, a modification of the lens driving device 1 according to the first embodiment of the present invention will be described. This modification is the same as the first embodiment except for the method of forming the adhesive.

In this modification, the adhesive sheets 33 and 35 are not attached, but adhesives provided on both surfaces of the first and second magnetic bodies 32 and 34 are previously applied to both surfaces of the first and second magnetic bodies 32 and 34. It is to be formed. That is, as shown in FIG. 7 , adhesive substances 33A and 35A serving as adhesives are applied to both surfaces of the first and second magnetic bodies 32 and 34, respectively. In addition, plate | board thickness L1 of the 1st, 2nd magnetic bodies 32 and 34 shall be 0.2-0.3 mm.

When the first and second magnetic bodies 32 and 34 are formed by punching into a press, as shown in FIG. 8 , burr or burr 32a and 34a similar to the burr may be generated. In this embodiment, the side on which the burrs and burr 32a and 34a are present is the side that contacts the first case divided body 26 and the second case divided body 42. By doing so, the first drive coil 28 and the second drive coil 30 do not come into contact with the side where the burr and burr 32a and 34a are present, and there is a risk of disconnection due to the burr or burr 32a and 34a. Can be eliminated.

  Moreover, when manufacturing the 1st, 2nd magnetic bodies 32 and 34 with a press, the burr 32a and 34a will be about 5 to 10% with respect to plate | board thickness L1. For this reason, when using the adhesive sheets 33 and 35 as the adhesive, the thickness of the adhesive layer needs to be at least 20 to 30 μm. In the case of the adhesive substances 33A and 35A, the thickness of the adhesive substance is required to be at least 20 to 30 μm. In addition, the thickness of the pressure-sensitive adhesive needs to be about 5 to 10% of the plate thickness L1, that is, 10% or more. However, the thickness of the pressure-sensitive adhesive is the plate thickness L1 from the viewpoint of thinning. 50% or less, preferably 25% or less. When the plate thickness L1 is 0.2 to 0.3 mm, the thickness of the pressure-sensitive adhesive is 100 to 150 μm or less, preferably 50 to 75 μm or less.

Then, the lens driving device 1A according to a second embodiment of the present invention will be described with reference to FIGS. 9-11.

The lens driving device 1A has substantially the same configuration as the lens driving device 1 according to the first embodiment. A different point is a method of forming a gap g1 (see FIG. 9 ) that is the maximum gap length between the projection 36 serving as the front contact portion and the lens holder 10. This gap g1 is the maximum gap length between the lens holder 10 and the protrusion 36, and the state is shown in FIG . In the state of FIG. 9 , the lens holder 10 abuts against the protruding edge 27 of the second case divided body 26 and has a limit of movement to the rear side. In this embodiment, the maximum gap length is equal to the movement range of the macro position where the lens holder 10 moves and the normal photographing position (standard position), but the macro where the lens holder 10 moves over the maximum gap length. You may make it become longer than the movement range of a position and a standard position.

In order to form the gap g1, the first and second case division bodies 26 and 42 are fitted together. Before, as shown in FIG. 10 , the spacer 76 is arrange | positioned between the 2nd case division body 42 and the lens holder 10, and the 1st, 2nd case division bodies 26 and 42 are integrated. Then, in a state where the spacer 76 is firmly sandwiched between the protrusion 36 and the lens holder 10, the first and second case division bodies 26 and 42 are completely integrated by using an adhesive or welding.

As shown in FIGS. 10 and 11 , the spacer 76 has a flat plate shape, has a plurality of protrusions 76 a on the outer periphery, and has two through holes 76 b and 76 b in the central portion. The spacer 76 is in a state in which one thread 77 is passed through the two through holes 76b and 76b before being assembled between the second case divided body 42 and the lens holder 10. Incorporated while maintaining the state, is the state shown in FIG. 10. That is, both ends of one thread 77 are drawn outward from the opening 42e of the second case divided body 42, and the first and second case divided bodies 26, 42 are integrally fixed in this state. Thereafter, the spacer 76 is pulled out with both ends of the thread 77. As a result, the thickness of the spacer 76 becomes equal to the gap g1 which is the maximum gap length.

The spacer 76 is a flexible synthetic resin sheet. In addition, an adhesive is applied to one side of the spacer 76, and by making the one side of the spacer 76 the projecting portion 36 side, the spacer 76 can be in a state of being adhered to the projecting portion 36 (see FIG. 10 ). Moreover, the spacer 76 can be hold | maintained at the lens holder 10 by making the adhesive side into the lens holder 10 side. The spacer 76 may be another member such as a hard rubber material or paper material. Further, the adhesive may not be provided on one side of the spacer 76.

  In the lens device 1A according to the second embodiment, when the first and second case division bodies 26 and 42 are integrated, the distance between the imaging element 44 and the lens 14 is not adjusted. Also in the second embodiment, the maximum gap length is equal to the maximum movement range between the macro position where the lens holder 10 moves and the standard position, as in the first embodiment. After the parts are configured as the case body part, the case body part is delivered to the camera manufacturer or the portable device manufacturer, and after the delivery, the distance to the image sensor 44 is adjusted. In this adjustment, images at both the normal shooting position and the macro shooting position are acquired, and the case body is fixed to the image sensor case 47 at a position where the images at both positions are balanced. The manufacture of the case body and the fixing of the case body and the image sensor case 47 may be performed within the same manufacturer.

Will be described below with reference to FIGS. 12 to 15 for the modification of the second embodiment of the lens apparatus 1A.

In this modified example, the second case divided body 42A having a shape that makes it easy to remove the spacer 76 is employed. Since the other points are the same as those of the lens driving device 1A, only the configuration of the second case divided body 42A will be described. The second case divided body 42A is provided with a plurality of cutout recesses 81 in the opening 42e and an inclined surface 82 on the inner peripheral surface of the inner wall 42d surrounding the ring-shaped groove 42c with a U-shaped section. It is. In the second case divided body 42A, the wall 42d forming the groove 42c serves as the protrusion 36 instead of the protrusion 36 in the lens driving device 1. The wall 42d is formed in a ring shape as shown in FIG. 14 , and the protrusion 76a of the spacer 76 comes into contact with the end surface of the wall 42d.

  The second case divided body 42A further includes protrusions 83 and 83 for winding the end of the second power supply line 74, cutouts 84 and 84 for taking out the second power supply line 74 to the outside, and the back of the groove 42c. Ring-shaped small grooves 85, 85 and an inclined surface 86. The small groove 85 is for holding and fitting the second magnetic body 34 in the groove 42c so as not to float accurately. In addition, the inclined surface 86 provided over the entire circumference at the tip of the inner peripheral surface of the overhanging portion 42a is for smoothly engaging the overhanging portion 26a. The protrusion 83, the notch 84, and the small groove 85 are also provided on the first case divided body side of the modified example of the lens driving device 1A.

  Each of the embodiments described above and the modifications thereof are suitable examples of the present invention, but various modifications can be made without departing from the scope of the present invention. For example, the present invention is not limited to switching between normal shooting and macro shooting, but can be applied to any lens that needs to switch the position of the lens 14 to two or three or more positions. Specifically, as a collapsible mechanism of a collapsible camera that houses a lens barrel in the body of a camera or portable device when not in use, or a camera that can switch the focal length between a short focal position and a long focal position. It can also be applied to a focal length switching mechanism. Furthermore, the present invention can be applied not only to a lens driving device that switches between a macro photographing position and a normal photographing position, but also to a lens driving device having a zoom photographing function that independently drives two lenses with a drive motor or the like.

  Further, in each of the above-described embodiments, an adhesive is provided on both surfaces of the first and second magnetic bodies 32 and 34, and the first and second case division bodies 26 and 42 and the first and second drives are provided with the adhesive. Although an example in which the coils 28 and 30 are integrally fixed via the first and second magnetic bodies 32 and 34 has been shown, the first and second drive coils are not provided without providing the first and second magnetic bodies 32 and 34. The present invention can also be applied to a case where 28 and 30 are directly integrated with the first and second case division bodies 26 and 42. In that case, any one of the three methods is adopted in which the adhesive is provided on the first and second case division bodies 26, 42, provided on the first and second drive coils 28, 30 side, or both. be able to.

  Further, only when the first and second magnetic bodies 32 and 34 are integrated with the first and second case division bodies 26 and 42, an adhesive is used, or the first and second drive coils 28 and 30 Adhesive is used only for fixing to the first and second magnetic bodies 32, 34, or adhesive is used only when fixing the first and second drive coils 28, 30 to the grooves 26c, 42c. Also good. In the case where an adhesive is used when fixing the first and second drive coils 28 and 30 to the grooves 26c and 42c, the adhesive is provided on the winding outer peripheral surface of the first and second drive coils 28 and 30, Either of the methods provided on the inner peripheral surfaces of the grooves 26c and 42c is adopted.

Moreover, when attaching components to the case body 24 using an adhesive, it is preferable to use a pressing process in combination to prevent the attached components from floating. Further, when the adhesive sheets 33 and 35 are provided on the first and second magnetic bodies 32 and 34, the colors of the release papers on both sides are made different so that the direction of bounce of the pressed first and second magnetic bodies 32 and 34 is clear. Can be adopted. Furthermore, in the above-described embodiment, the first and second magnetic bodies 32 and 34 have a cutout portion 32b on the outer periphery as shown in FIG. 6 , but a recess is provided instead of the cutout portion 32b. You may do it. In the case of the concave portion, the concave portion can be used as an adhesive reservoir for fixing and reinforcement in addition to peeling of the release paper.

  Moreover, you may make it provide a U-shaped dent in two or more places of the outer periphery or inner periphery of the groove | channels 24c and 42c provided in the case body 24. FIG. The dent is continuous with the grooves 24c and 42c and extends in the direction of the optical axis 11, and is U-shaped when viewed from the direction of the optical axis 11. When this recess is provided, when the first and second magnetic bodies 32 and 34 are attached to the first and second case divided bodies 24 and 42, the attachment can be easily performed by inserting tweezers using the recess. At the same time, after fixing, the release paper on the upper surface side can be easily peeled off by inserting tweezers. Moreover, it becomes possible to pour the adhesive for reinforcement | strengthening into the dent.

  The pressure-sensitive adhesive employed in each embodiment is an insulating material and performs an insulating function, but a conductive pressure-sensitive adhesive may be used. As the pressure-sensitive adhesive, various pressure-sensitive adhesives such as a rubber-based pressure-sensitive adhesive, a vinyl-based pressure-sensitive adhesive, and a silicon-based pressure-sensitive adhesive can be employed in addition to the acrylic pressure-sensitive adhesive. Functionally, a permanent adhesion (strong adhesion) type is preferable, but a re-peeling (weak adhesion) type may be employed.

In the above-described embodiment, the lens driving device 1A employing the spacer 76 is an example in which an adhesive is used for the first and second magnetic bodies 32 and 34. The use can also be applied to a lens driving device that does not use an adhesive. Further, as shown in FIG. 16 , the spacer 76 may be a spacer 91 having a plurality of notches 91 a around it and one through hole 91 b in the center, or a cross-shaped spacer 92. The cross-shaped spacer 92 has a plurality of protrusions 92a and one through hole 92b. In addition, the thread | yarn which formed the knurled part through the through-holes 91b and 92b is passed, and the knot is incorporated so that it cannot penetrate the through-holes 91b and 92b.

  In addition to the spacers 76, 91, and 92, the spacer may have other shapes such as a star shape or a petal shape. In any case, it is preferable in terms of extraction that a protrusion is provided on the outer periphery and that the protrusion radiates in the radial direction from the center.

  Further, the spacer 76 may be provided not on the second case divided bodies 42 and 42A but on the first case divided body side. When the spacer is provided, the shape of the opening 42e of the second case divided body 42 and the shape of the opening of the first case divided body 24 are set so that the spacers are easily removed from the first and second case divided bodies 24, 42, 42A. In addition to the above examples, a star shape, a petal shape, or the like may be used. In any case, the shape of the opening is preferably a shape in which a part protrudes (radiates) from the center in the radial direction in terms of extracting the spacer.

  Further, in each of the above-described embodiments and modifications, the example in which the lens driving device 1 or 1A is incorporated as the mechanism of the camera portion of the camera-equipped mobile phone is shown. However, these lens driving device and thin camera are mobile computers. It can be used for other portable devices such as PDAs, or can be incorporated into other camera devices such as surveillance cameras and medical cameras, and electronic devices such as automobiles and televisions.

  The present invention can be applied to a camera device. Further, the present invention can be applied to a mobile device such as a mobile phone having a camera function. Furthermore, any electronic device having a lens position switching mechanism can be incorporated into all electronic devices.

It is sectional drawing which shows the lens drive device which concerns on the 1st Embodiment of this invention. It is an external view which shows the case body part of the lens drive device which concerns on the 1st Embodiment of this invention. It is an exploded sectional view showing a case body part of a lens drive device concerning a 1st embodiment of the present invention. It is a top view which shows the drive magnet which concerns on the 1st Embodiment of this invention. It is a figure for demonstrating the method to affix an adhesive sheet on the 1st magnetic body used for the lens drive device of FIG. It is a top view of the 1st magnetic body used for the lens drive device of FIG. FIG. 6 is a cross-sectional view of a main part of the first and second magnetic bodies, showing a modification of the lens driving device according to the first embodiment of the present invention. In the lens drive device concerning a 1st embodiment of the present invention, it is an important section sectional view when a burr occurs in the 1st and 2nd magnetic bodies. It is principal part sectional drawing which shows the lens drive device which concerns on the 2nd Embodiment of this invention. In the lens drive device which concerns on the 2nd Embodiment of this invention, it is sectional drawing of the 2nd case division body part which shows the state in which a spacer is installed. It is a top view which shows the spacer used when manufacturing the lens drive device of FIG. FIG. 14 is a cross-sectional view of a second case divided body, showing a modification of the lens driving device according to the second embodiment of the present invention, and a cross-sectional view taken along the line A-O-B in FIG. 13 . It is the top view seen from the arrow A direction of FIG. It is a bottom view seen from the arrow B direction in FIG. 12. It is a partial cross-sectional view taken along C-C cutting line of Figure 13. It is another example of a spacer used when manufacturing the lens driving device of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Lens drive device 10 Lens holder 12 Lens barrel 14 Lens 14a Subject side lens 14b Camera body side lens 14c Space | interval holding member 14d Position fixing member 16 Drive magnet (1st magnetic means)
18 Entrance window 20 Front end face 24 Case body (fixed body)
26 1st case division (case half)
26c Ring-shaped groove 28 First drive coil (part of second magnetic means)
30 Second drive coil (part of second magnetic means)
32 1st magnetic body (a part of 2nd magnetic means)
33 Adhesive sheet (adhesive)
34 Second magnetic body (part of second magnetic means)
35 Adhesive sheet (adhesive)
36 Projection part 42 Second case division body (case half body)
42c Ring-shaped groove 43 Filter 44 Image sensor 45 Circuit board 46 Rear end member 47 Image sensor case 62, 64 Notch 72 First power supply line (power supply member)
74 Second feeder (feeding member)
76 Spacer g1 Gap (Maximum air gap length)

Claims (4)

A lens holder with a lens;
In the method for manufacturing a lens driving device, the lens holder is moved in the optical axis direction of the lens and has a fixed body that holds the lens holder.
The fixed body is configured by a case body that houses the lens holder therein, and the case body is configured to be divided into at least two parts, each of which is a case half,
The lens holder is brought into contact with a contact portion as a movement limit provided in the one case half, and a contact portion as a movement limit provided in the other case half and the lens holder. A method of manufacturing a lens driving device, wherein the one case half and the other case half are fixed so as to sandwich a spacer therebetween, and then the spacer is pulled out. At least one through hole is formed in the spacer, and a sampling member is passed through the through hole.
The method of manufacturing a lens driving device according to claim 1, wherein the spacer is extracted by pulling the extraction member. A protrusion is provided on the outer periphery of the spacer, and a notch recess is provided on the edge of the opening of the lens formed in the other case half,
The method of manufacturing a lens driving device according to claim 1, wherein the spacer is extracted by passing the protrusion through the notch recess.   Before sandwiching the spacer between the lens holder and the contact portion as the movement limit provided on the other case half, the spacer is previously adhered to the contact portion with an adhesive material. The method for manufacturing a lens driving device according to claim 1, wherein:

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