KR20200011533A - Lens drive device, camera device, and electronic device - Google Patents

Abstract

The present invention provides a lens driving device which can be miniaturized, a camera device, and an electronic device. To this end, a lens driving device (18) includes: a lens carrier (52, 54) for fixing a lens barrel (14, 16) to the inside; a driving unit for moving the lens carrier (52, 54) toward an optical axis of the lens barrel (14, 16); a guide unit (116) for guiding a movement of the lens carrier (52, 54); and a casing (12) for accommodating the lens carrier (52, 54), the driving unit, and the guide unit (116). The driving unit has: a driving shaft (62) extended to the optical axis of the lens barrel (14, 16) to be connected to the lens carrier (52, 54) and supported on the casing (12); and a vibration member (60) fixed to the driving shaft (62) and vibrating the driving shaft (62) in the axial direction. The lens carrier (52, 54) has an opening unit (52a, 54a) in which the lens barrel (14, 16) is inserted in the direction crossing the direction of the optical axis of the lens barrel (14, 16).

Description

LENS DRIVE DEVICE, CAMERA DEVICE, AND ELECTRONIC DEVICE}

The present invention relates to a lens drive device, a camera device, and an electronic device.

Electronic devices such as mobile phones and smart phones are equipped with small cameras. Small cameras of this kind are of autofocus type. The compact camera of the autofocus type is provided with a lens driving device for driving a lens barrel.

Patent document 1 discloses the lens drive apparatus which fixes a focus by fixing a lens barrel inside a lens carrier, and moving a lens carrier to the optical axis direction of a lens barrel.

Japanese Patent Application Laid-Open No. 2010-134409

In the above-described conventional example, the main body is provided with an opening opening in the optical axis direction of the lens barrel, the lens barrel is inserted in the optical axis direction through the opening, and the lens barrel is fixed to the lens carrier. The lens barrel is slidably inserted into the lens carrier without forming a screw groove between the lens barrel and the lens carrier. For this reason, in the said patent document 1, since it is not necessary to form a screw thread in both a lens barrel and a lens carrier, it is described that the lens drive apparatus can be miniaturized by that much.

However, since the lens barrel is inserted into the lens carrier by sliding from the optical axis direction, a wall surface for sliding the lens barrel around the lens carrier is required, so that the lens carrier cannot be made small, which is an obstacle to miniaturization of the lens driving device. there was.

An object of the present invention is to provide a lens driving apparatus, a camera apparatus, and an electronic apparatus that can be miniaturized by solving the above-mentioned conventional problems.

One aspect of the present invention provides a lens carrier for fixing a lens barrel therein, drive means for moving the lens carrier in an optical axis direction of the lens barrel, guide means for guiding movement of the lens carrier; And a casing accommodating the lens carrier, the driving means, and the guide means, wherein the driving means extends in the optical axis direction of the lens barrel and is connected to the lens carrier and is supported by the casing; It has a vibration member which is fixed and vibrates the said drive shaft to an axial direction, The said lens carrier is a lens drive apparatus provided with the opening part which can insert the said lens barrel from the direction which cross | intersects the optical axis direction of the said lens barrel.

Preferably, the guide means is provided on the side opposite to the drive means with the lens barrel interposed therebetween.

Preferably, the guide means has a guide portion extending in the optical axis direction of the lens barrel, a guide portion formed in the lens carrier to abut the guide portion, and slidably supporting the lens carrier. In addition, this guide part may be provided in the said casing.

Preferably, at least one of the guide portion and the guided portion is provided with a protrusion protruding to the other side.

Preferably, the guide portion is a through hole provided in the optical axis direction in the lens carrier, and the guide portion is a guide shaft inserted into the through hole and fixed to the casing.

Preferably, the guide portion is a notch penetrating through the lens carrier in the optical axis direction, and the guide portion is a guide shaft inserted into the notch and fixed to the casing.

Preferably, the guide means has a guide groove extending in the optical axis direction and a ball disposed between the guide groove and the lens carrier.

Preferably, the lens carrier is supported on the drive shaft through a support mechanism,

The support mechanism has a clamping member provided on the lens carrier and clamping the drive shaft so as to be in frictional contact with the drive shaft, and a pressing portion provided on the lens carrier to press the clamping member toward the drive shaft.

Preferably, the optical member which forms the optical system of a bending optical axis is arrange | positioned in the optical axis direction of a lens barrel.

Another aspect of the present invention is a camera device including a lens driving device and an image sensor that receives light passing through the lens barrel.

Another aspect of the present invention is an electronic device having the camera device described above.

According to the present invention, since the opening for allowing the lens barrel to be inserted into the lens carrier is provided from the direction crossing the optical axis direction of the lens barrel, the size of the lens carrier can be made small so that the lens driving device, the camera device and the electronic device can be provided. It can be miniaturized.

1 is a perspective view showing a camera device according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along the line AA of FIG. 1 showing a camera apparatus according to an embodiment of the present invention. FIG.
3 is a cross-sectional view taken along line BB of FIG. 1 showing a camera apparatus according to an embodiment of the present invention.
4 is a perspective view of an actuator used in one embodiment of the present invention.
The figure which shows the cross section of the actuator used for one Embodiment of this invention, and a drive circuit.
6 is a perspective view showing a support mechanism and its periphery in an embodiment of the present invention.
7 is a cross-sectional view taken along line CC of FIG. 3 in one embodiment of the present invention.
8 is a perspective view showing a vibration member of an actuator and its periphery in an embodiment of the present invention.
9 (a) and 9 (b) are cross-sectional views schematically illustrating other guide means in one embodiment of the present invention, respectively.
10 is a cross-sectional view schematically showing still another guide means in one embodiment of the present invention.

One embodiment of this invention is described based on drawing.

1 to 3, a camera apparatus 10 according to an embodiment of the present invention is shown. The camera apparatus 10 is used as an autofocus compact camera apparatus used for electronic devices, such as a mobile telephone and a smart phone, for example.

The camera device 10 has a rectangular parallelepiped casing 12 formed in one direction.

In this casing 12, the lens barrel 14 for zoom and the lens barrel 16 for focus which are mentioned later, and the lens drive apparatus 18 which drive these lens barrel 14 and the lens barrel 16, respectively, 18) are installed respectively.

In addition, in FIG. 1, the casing 12 is shown with the dashed-dotted line for clarity.

In addition, the optical axes of these lens barrels 14 and 16 are provided so that they may coincide. In this specification, as shown in FIG. 1, one side of the optical axis direction of the lens barrels 14 and 16 is followed by the other, One side in one direction orthogonal to the optical axis direction of the lens barrels 14 and 16 is called up, the other side is down, and one side in one direction orthogonal to this is called left and the other side is right. In addition, the optical axis of the lens barrels 14 and 16 may only be called an optical axis.

The casing 12 includes a first member 20 serving as a base, a second member 32 constituting the first side 22 and a second side 24, and a third side 26. 3rd member 33 which comprises this, 4th member 34 which comprises the 4th side surface 28, and 5th member 36 which comprises the 5th side surface 30 is provided.

The first member 20 is provided at one end in the longitudinal direction of the camera device 10. A light receiving window 38 is formed on the upper surface of the first member 20. Under the light receiving window 38, a prism lens 40 is disposed. The prism lens 40 forms an optical system of a curved optical axis, and has, for example, a reflecting surface 42 formed at 45 degrees, and the light received through the light receiving window 38 from above by the reflecting surface 42. The reflection is guided in the longitudinal direction of the camera device 10. In addition, the first intermediate lens 44 is disposed on the first member 20 in succession to the prism lens 40. One end of the second member 32, the third member 33, and the fourth member 34 is fixed to the first member 20. In addition, the fifth member 36 is fixed to the other ends of the second member 32, the third member 33, and the fourth member 34.

The first side 22, the second side 24, the third side 26 and the fourth side 28 composed of the second member 32, the third member 33 and the fourth member 34 are As shown in FIG.2 and FIG.3, the cross-sectional square frame is comprised. That is, the 1st side surface 22 is a lower surface (bottom surface), for example, and is raised integrally so that the 2nd side surface 24 may be 90 degrees from this 1st side surface 22. As shown in FIG. In addition, the 3rd side surface 26 is an upper surface, and is continuous so that it may become 90 degrees from the 2nd side surface 24, for example. The fourth side 28 faces downward so as to be 90 ° from the third side 26 and is fixed to the first side 22 which is the lower surface at the lower end of the fourth side 28.

As shown in FIG. 1, in the space surrounded by the first side surfaces 22 to the fourth side surfaces 28, the lens barrel 14 and the second intermediate lens for zooming from the first intermediate lens 44 toward the longitudinal direction. 46 and the lens barrel 16 for focusing are arrange | positioned. In addition, an image sensor 48 is disposed behind the focus lens barrel 16. This image sensor 48 is fitted into the image sensor attachment hole 50 (shown in FIG. 3) formed in the 5th member 36, and is fixed.

The first intermediate lens barrel 44, the lens barrel 14 for zooming, the second intermediate lens barrel 46, and the lens barrel 16 for focusing are arranged along one optical axis, and through the prism lens 40. The received light is formed in the image sensor 48.

The lens drive devices 18 and 18 have a lens carrier 52 for zoom and a lens carrier 54 for focus. The lens carrier 52 for zoom and the lens carrier 54 for focus are each formed as a rectangular frame, and the lens barrel 14 for zoom and the lens barrel 16 for focus are fixed inside, respectively. The lens carrier 52 for zoom and the lens carrier 54 for focus are moved in the longitudinal direction (optical axis direction) of the camera device 10 in a space surrounded by the first side surfaces 22 to the fourth side surfaces 28. Supported to be possible.

In addition, the second intermediate lens barrel 46 is supported by the second intermediate lens support body 56 and fixed to the casing 12 unlike the lens barrel 14 for zooming and the lens barrel 16 for focusing. It is.

As shown in FIG. 1 and FIG. 2, the lens carriers 52, 54 are formed with openings 52a, 54a that allow the lens barrels 14, 16 to be inserted therein. These openings 52a and 54a are opened in a direction intersecting with the optical axes of the lens barrels 14 and 16, for example, upward. These openings 52a and 54a are adapted to insert the lens barrels 14 and 16 into the lens carriers 52 and 54 from above through these openings 52a and 54a prior to attachment of the third member 33 when assembled. It is.

In addition, the lens drive devices 18 and 18 have actuators 58 and 58 as drive means. As shown in FIG. 4, the actuators 58 and 58 are a bimorph piezoelectric type, for example, the vibration member 60 and the drive shaft 62 fixed to this vibration member 60. As shown in FIG. Has The drive shafts 62 and 62 extend in the optical axis direction, are connected to the lens carriers 52 and 54 and are supported by the casing 12. In addition, as described later, the drive shafts 62 and 62 vibrate in the axial direction by the vibration members 60 and 60. The vibrating member 60 has two rectangular flat piezoelectric elements 64 and 66, respectively. Similarly, the rectangular plate-shaped electrode plate 68 is interposed between the piezoelectric elements 64 and 66. That is, the piezoelectric elements 64 and 66 and the electrode plate 68 are fixed to each other by matching the plate surface. Electrode layers 70 and 72 are formed on the front and back surfaces of the piezoelectric elements 64 and 66 as shown in FIG. 5. The drive shaft 62 is fixed to the electrode layer 70 of one piezoelectric element 64 via an adhesive 74. The electrode plate 68 is composed of, for example, a metal plate having elasticity. From this electrode plate 68, the electrical connection part 76 protrudes from the substantially center of one square side.

As shown in FIG. 5, the electrode layers 70 and 72 exposed on the surface of the vibrating member 60 are connected to, for example, the positive side of the power supply control unit 78, and the electrode plate 68 is connected to the electrical connection 76. Is connected to the minus side (ground) of the power supply control unit 78 through. When a pulse voltage is repeatedly applied between one electrode layer 70 and electrode plate 68, the piezoelectric element 64 is energized so that one piezoelectric element 64 is stretched and the vibrating member 60 is It is repeated to deform into a bowl shape toward one direction and to return to the original flat shape rapidly by the elasticity of the electrode plate 68. Along with this, the drive shaft 62 also repeats a small reciprocating movement in the axial direction. When the pulse voltage is repeatedly applied between the other electrode layer 72 and the electrode plate 68, the other piezoelectric element 66 stretches and the vibration member 60 deforms into a bowl shape toward the other direction. And attempting to return to the original flat form rapidly by the elasticity of the electrode plate 68 are repeated. Along with this, the drive shaft 62 also repeats a small reciprocating movement in the axial direction.

In addition, in this embodiment, although the bimorph type piezoelectric actuator was used as the actuators 58 and 58, it is not limited to this, For example, other types of piezoelectric actuators, such as a unimorph type and a laminated type, or an electrostatic actuator You can also use In addition, the shape of the piezoelectric elements 64 and 66 and the electrode plate 68 does not need to be rectangular, for example, It may be circular.

As shown in FIGS. 1 to 3, the actuators 58 and 58 have the lens carriers 52 and 54 and the fourth side surface such that the driving shafts 62 and 62 are different from each other in the longitudinal direction in the casing 12. It is arrange | positioned in the space formed between 28. The lens carriers 52 and 54 are slidably supported by the drive shafts 62 and 62 via the support mechanisms 80 and 80 described later.

On the opposite side of the actuators 58, 58, which are driving means, with the lens carriers 52, 54 interposed therebetween, as the guide means 116, a corner portion between the first side 22 and the second side 24 is provided. Guides 82 and 84 are formed at the corners between the second side face 24 and the third side face 26. In this embodiment, the guide part 82 protrudes upwards and to the right (fourth side surface 28 direction). In addition, the guide portion 84 protrudes downward and to the right (fourth side 28). The guide parts 82 and 84 are formed along the optical axis direction which is the longitudinal direction of the casing 12.

However, in this embodiment, the guide part 82 is not formed in the part of the 2nd intermediate lens holder 56, and the front-back part of the 2nd intermediate lens holder 56 is between the guide parts 82. The second intermediate lens holder 56 is positioned with respect to the casing 12.

On the other hand, in the lens carriers 52 and 54, guide parts 86 and 88 are formed in the upper and lower corners on the second side face 24 side corresponding to the guide parts 82 and 84. In this embodiment, the guide parts 86 and 88 are formed with concave grooves 90 and 92 corresponding to the projections of the guide parts 82 and 84 in the longitudinal direction, and the guide parts 82 and 84 and the guide parts. The rail is comprised by the 86 and 88. Further, projections 94 and 96 are formed on the upper and lower surfaces of the recessed grooves 90 and 92 so as to project toward the guide portions 82 and 84. The protrusions 94 and 96 have a hemispherical shape, for example, and are formed in a plurality of locations (two locations along the guide portions 86 and 88 in this embodiment) of the lens carriers 52 and 54, respectively.

Upper and lower surfaces of the above-described guide parts 82 and 84 abut the ends of the protrusions 94 and 96 of the guide parts 86 and 88. The lens carriers 52, 54 are slidably supported along the longitudinal direction of the casing 12 by being sandwiched between the guides 82, 84 formed at the upper and lower corners of the second side surface 24. Therefore, the lens carrier 52, 54 is restrict | limited the rotational motion (operation | movement of the up-down direction in the guide part 86, 88) centering on the drive shaft 62, 62, respectively. In addition, the second side surface 24 and the lens carriers 52 and 54 are parallel and have almost no gaps so that the lens barrels 14 and 16 and the drive shafts 62 and 62 are aligned (left and right directions in FIGS. 2 and 3). ) Width can be reduced. In addition, since the guide portions 86 and 88 contact only the tip ends of the projections 94 and 96, the contact area with the casing 12 of the lens carriers 52 and 54 is small, and thus the lens carriers 52 and 54 are used. The friction generated between the casing 12 and the casing 12 can be reduced to guide the lens carriers 52, 54 in the optical axis direction that is the longitudinal direction of the casing 12.

The projections 94 and 96 and the guides 84 and 86 are provided such that the lens carrier 52 or the lens carrier 54 is provided with a slight gap so that the lens carrier 52 or the lens carrier 54 is in contact with each other when the above-described rotational operation is always in contact. It is more preferable than that. It is possible to prevent wear of the protrusions 94 and 96 and to suppress unnecessary driving resistance. Of course, you can always make contact. Moreover, since the guide parts 82 and 84 are formed in the edge part of the casing 12 on the opposite side to the support mechanisms 80 and 80 with the lens carriers 52 and 54 interposed, the lens carriers 52 and 54 are provided. ), The center of the lens 14, 16 is smaller than that even if the above-described rotation operation within the regulation range.

In addition, guide portions 82 and 84 that face each other may be formed on the first side surface 22 and the third side surface 26. At this time, the guide portions 86 and 88 (protrusions 94 and 96) formed in the respective lens carriers 52 and 54 abut the guide portions 82 and 84, and the respective lens carriers 52 and 54 are brought into contact with each other. It is preferable to guide between the guide parts 82 and 84. That is, the upper and lower surfaces may be formed as the guide parts 82 and 84 and the guide parts 86 and 88 may be brought into contact with the upper and lower surfaces. In this case, the guides 82 and 84 need not be installed at the corners between the first side 22 and the second side 24 and the second side 24 and the third side 26, respectively. The first side face 22 and the third side face 26 may be provided to face each other.

In any case, since the arm is extended from the lens carriers 52 and 54 to the opposite side of the drive shaft 62 between the lens barrels 14 and 16 as the guide means, the dimension in the left and right directions can be reduced. Therefore, the lens drive device 18 can be miniaturized.

The support mechanism 80 has the same structure on both the zoom lens side and the focus lens side. For example, the focus lens side will be described. As shown in FIG. 2 and FIG. 6, the support mechanism 80 has the support part 98 which protruded in block shape from the focus lens carrier 54 to the 4th side surface 28 side integrally with the lens carrier 54. As shown in FIG. Formed. The support portion 98 has a support groove 100 open in a V-shape toward the drive shaft 62 in parallel with the drive shaft 62. Moreover, the fitting parts 102 and 102 which protruded from the support groove 100 to the 4th side surface 28 side continuously are formed in the support part 98 up and down. The fitting portions 102, 102 are formed with fitting grooves 104, 104, respectively.

The clamping members 106 and 106 are provided between the fitting piece portions 108 and 108 fitted to the fitting grooves 104 and 104 of the fitting portions 102 and 102, respectively, and the upper and lower fitting piece portions 108 and 108, respectively. It has branches 110 and 110. The clamping parts 110 and 110 are formed in a substantially semicircular shape in which the drive shaft 62 side is concave. The drive shaft 62 is sandwiched between these clamping parts 110 and 110. The clamping parts 110 and 110 are in contact with the drive shaft 62 in two vertical directions, respectively (four points in total). Moreover, the clamping part 110 of the 4th side surface 28 side is pushed toward the drive shaft 62 side by the press part 120 of the press member 112. As shown in FIG. Therefore, at least one of the upper fitting piece 108 and the lower fitting piece 108 is separated from each other.

The pressing member 112 is provided with a locking portion 114 formed in a C shape when viewed from above. On the other hand, the upper surface of the support portion 98 is formed with a protrusion 118 protruding upwards, the locking portion 114 is sandwiched from both sides of the protrusion 118 so that the locking portion 118 is locked around the protrusion 118. And the pressing member 112 is fixed to the support part 98. In this way, since the locking portion 114 of the pressing member 112 is secured by fixing the protrusion 118 of the support portion 98, the protrusion of the support portion 98 is reduced to lower the upper and lower portions of the camera device 10. The width of the direction can be made small. In addition, the pressing member 112 is formed with a flat pressing portion 120 extending downward from the locking portion 114, the clamping portion 110 is driven by the elasticity of the pressing portion 120 is driven shaft 62 It is sandwiched between them. By such a structure of the support mechanism 80, the lens carrier 54 is supported by the drive shaft 62 with appropriate friction.

In addition, each of the drive shafts 62 and 62 is provided with a casing 12 through a bush (elastic member) 122 made of an elastic body so as to be vibrated to the casing 12 at two positions, for example, at the base portion and the tip portion. Is supported.

That is, as shown also in FIG. 7, the bush 122 has the flange parts 124 and 124 arrange | positioned at the front and back sides, and the engaging part 126 arrange | positioned between the said flange parts 124 and 124. As shown in FIG. The engaging portion 126 is formed, for example, as a concave portion having a rounded circumferential direction. The insertion hole 128 is formed in the center of this bush 122, and the drive shaft 62 is inserted in this insertion hole 128 so that the insertion hole 128 may be opened. The bush 122 and the drive shaft 62 on the far side from the vibrating member 60 are fixed to each other, but the bush 122 and the drive shaft 62 on the near side are not bonded.

Inside the first side surface 22 (lower surface) of the casing 12, a first supporting protrusion 130 is formed to face the engaging portion 126 of the bush 122. Moreover, inside the third side surface 24 (upper surface) of the casing 12, a second support protrusion 132 is formed to face the engaging portion 126 of the bush 122. The first support protrusion 130 is formed with a semi-circular first engagement groove 134 concave downward, while the second support protrusion 132 is formed with a semi-circular second engagement groove 136 upwardly concave. have. The tip ends of the first support protrusion 130 and the second support protrusion 132 abut, and the circular engagement portion 126 of the bush 122 is a semi-circular first engagement groove 134. The drive shaft 62 is supported by the casing 12 so as to be vibrated (particularly in the axial direction of the drive shaft 62) between the second engagement groove 136 and the second engagement groove 136.

In the casing 12, a lens barrel position detector 138 for zooming and a lens barrel position detector 140 for focusing are provided. Each of the lens barrel position detectors 138 and 140 has the same structure, and magnetic pole members 142 and 144 alternately arranged with different magnetic poles (S-pole and N-pole) along the longitudinal direction of the camera apparatus 10. And MR sensors 146 and 148 (only MR sensor 148 is shown in FIG. 6) for detecting magnetic field strength. The MR sensors 146 and 148 are MR sensor holding parts 150 which protrude toward the fourth side surface 28 integrally with the lens carriers 52 and 54 under the support portion 98 of the lens carriers 52 and 54, respectively. , 150). The magnetic pole members 142, 144 are fixed to the first side 22 of the casing 12 opposite the MR sensors 146, 148. When each lens carrier 52, 54 is moved, the amount of movement and the direction of movement of each lens carrier 52, 54 are detected by the MR sensors 146, 148 as a change in the magnetic field intensity, and the detected change in the magnetic field intensity is detected. Indicated signals are output from the MR sensors 146 and 148.

One MR sensor 146 is connected to a flexible wiring board for a first MR sensor (hereinafter referred to as a first MR FPC) 152. The first MR FPC 152 is bent from the first connecting portion 154 connected to the MR sensor 146 and extends upward on the zoom lens side, and the first side surface 22 is notched to lengthen the casing 12. It extends downward through the space part 156 formed in the center substantially in the direction, and is drawn out from the lower side of the 1st side surface 22 to the 5th side surface 30 side. The other MR sensor 148 is connected to a flexible wiring board for a second MR sensor (hereinafter referred to as a second MR FPC) 158. The 2nd MR FPC 158 is bent from the 2nd connection part 160 connected to the MR sensor 148, and is extended above a focus lens side, The 1st MR FPC 152 is carried out in the space part 156 mentioned above. ) Is pulled out toward the fifth side surface 30 side.

In the vibrating members 60 and 60 of the above-mentioned actuators 58 and 58, the flexible wiring board is similarly connected. That is, as shown in FIG. 8, each vibrating member 60, 60 is exposed to the space part 156 mentioned above, and the flexible wiring board for 1st vibrating members connected to one vibrating member 60 (following) The first vibration member FPC) 162 extends downward from one vibration member 60 and is drawn out from the lower side of the first side surface 22 toward the fifth side surface 30. The flexible wiring board for second vibration member (hereinafter referred to as FPC for second vibration member) 164 connected to the other vibration member 60 extends downward from the other vibration member 60. It is integrated with the 1st vibrating member FPC 162, and is pulled out from the lower side of the 1st side surface 22 to the 5th side surface 30 side. The first vibrating member FPC 162 and the second vibrating member FPC 164 are divided into three, and the first terminal portion 166 is provided on the electrode layer 70 on the drive shaft 62 side of the vibrating member 60. The second electrode portion 168 is connected to the electrode layer 72 on the rear surface side, and the third electrode portion 170 is connected to the connection portion 76 for electricity supply of the electrode plate 68 using solder or the like. The first terminal portion 166 is formed in a crescent shape near the corner portion of the vibration member 60 away from the drive shaft 62 so as not to contact the adhesive 74 for fixing the drive shaft 62, and the center of the arc is the corner. It is arrange | positioned so that it may become negative. The second terminal portion 168 is formed in an annular shape at the center portion of the vibrating member 60. The 3rd terminal part 170 protrudes from the vibrating member 60 corresponding to the connection part 76 for electricity transmission, and is formed in square shape so that the connection part 76 for electricity transmission may be enclosed.

Next, the case where the lens lens 54 for focus is moved by the actuator 58 is demonstrated. As described above, when the pulse voltage is repeatedly applied to the actuator 58, the vibrating member 60 deforms into the bowl shape toward one direction and tries to return to the original flat plate shape rapidly. Along with this, the drive shaft 62 also repeats a small reciprocating movement in the axial direction. When deformed into a bowl shape toward one side, the lens carrier 54 is supported in frictional contact with the drive shaft 62 of the actuator 58 via the support mechanism 80, so that the lens carrier 54 is driven by the drive shaft 62. Move with). On the other hand, when the vibrating member 60 tries to quickly return to the original flat plate shape, the driving shaft 62 also moves in the reverse direction at high speed, and since the lens carrier 54 is high speed, it can follow the operation of the driving shaft 62. It does not return to its original position and stays there. Therefore, the lens carrier 54 moves by about one magnitude of the amplitude of the deformation of the vibrating member 60 in one operation. By repeatedly applying the pulse voltage, such movement can be repeatedly performed to move the lens carrier 54 to a desired position.

In this case, the lens carrier 54 is supported by the drive shaft 62 provided at approximately the center of the up-down direction on one side, and the guides 82 and 84 of the casing 12 which is the guide means provided on the opposite side up and down. Since it is guided in the longitudinal direction of 10, the lens carrier 54 can be moved stably.

In addition, the operation of the lens carrier 52 for zooming is the same as the lens carrier 54 for focusing.

In addition, although the protrusions 94 and 96 were made into hemispherical shape, it is good also as other shapes, such as a dice shape. In addition, although the protrusions 94 and 96 were provided in two places, one may be sufficient and three or more may be sufficient. The protrusions 94 and 96 may be formed of another member such as metal and adhered to the lens carriers 52 and 54. In addition, you may use lubrication means for at least one of the projections 94 and 96 or the guide parts 82 and 84. FIG.

In addition, although the guide parts 82 and 84 are formed in the shape which protrudes from an edge part, respectively, the guide parts 82 and 84 do not protrude, for example, the 1st side 22 and the 3rd side 26 itself. The guided parts 86 and 88 may be directly in contact with each other.

The actuators 58 and 58 are arranged such that the drive shafts 62 and 62 are different from each other in the longitudinal direction, but may be arranged to be in the same direction. In addition, only one side of the actuator 58 may be provided.

In addition, although the casing 12 was divided into 5 parts from the 1st member 20 to the 5th member 36, it may be another division | division division.

In addition, in the said embodiment, although the upper ends of the lens carriers 52 and 54 are higher than the upper ends of the lens barrels 14 and 16, they may be about the same height. In addition, the lens carriers 52 and 54 can be made thinner by employing other guide means. For example, the arm may be extended from the lens carriers 52 and 54 to the opposite side of the drive shafts 62 and 62 with the lens barrels 14 and 16 interposed therebetween. For example, as shown in Fig. 9A, a through hole 172 is provided in the optical axis direction on the arm extending from the lens carriers 52 and 54, and the guide shaft 174 extending in the optical axis direction is provided. It is good also as a structure which penetrates through this through-hole 172, and is fixed to the casing 12. FIG. In addition, as shown in FIG. 9B, a notch 176 that penetrates in the optical axis direction may be provided instead of the through hole 174. As shown in FIG. 10, as guide means, at least one of the casing 12 or the lens carriers 52, 54 is provided with guide grooves 180, 182 extending in the optical axis direction, and the guide groove 180 is provided. 182, the balls 184 and 186 may be arranged. Although only the left side is shown in FIG. 10, for example, a wall surface standing upright from the first side surface 22 is provided between the lens carriers 52, 54 and the actuators 58, 58, and the wall surface and the lens carriers 52, 54 are provided. You may arrange | position a ball between).

In addition, as in the above embodiment, since there is no special member in the upward direction of the lens barrels 14 and 16, the lens barrels 14 and 16 are suitable as the direction in which the lens carriers 52 and 54 are inserted. It is not limited to this. For example, the openings 52a and 54a of the lens carriers 52 and 54 may be formed to insert the lens barrels 14 and 16 from the left and right directions or the downward direction. In addition, this invention is not limited to the structure inserted in the direction orthogonal to the optical axis direction of the lens barrel 14, 16, What is necessary is just a direction which cross | intersects the optical axis direction of the lens barrel 14, 16, for example The lens barrels 14 and 16 may be inserted obliquely with respect to the optical axis direction. Moreover, in the said embodiment, although the prism lens 40 which is an optical member which forms the optical system of a bending optical axis is provided in the optical-axis direction of the lens barrel 14, 16, this invention provides such an optical member. This includes anything that is not installed.

10 camera device 12 casing
14, 16: lens barrel 22: the first side
24: second side 26: third side
28: fourth side 30: fifth side
52, 54: lens carrier 52a, 54a: opening
58: actuator 60: vibration member
62: drive shaft 80: support mechanism
82, 84: guide 86, 88: guide
94, 96: protrusion 106: clamping member
112: pressing member 116: guide means
120: press part 122: bush (elastic member)
130: first supporting protrusion 132: second supporting protrusion
138, 140: Lens Barrel Position Detector

Claims (10)

A box-shaped lens carrier for fixing a lens barrel therein for guiding light from a subject to a light receiving sensor,
The lens carrier has a first opening through which light from the subject is incident, a second opening through which light to the light receiving sensor is emitted, and a third opening for mounting the lens barrel,
The third opening is formed at an end of two box-shaped opposing sidewalls on a side other than the side where the first opening and the second opening are provided,
Inner surfaces of the two side walls are formed in parallel from the third opening to the center of the lens carrier.
Lens drive device. The method of claim 1,
An optical member provided between the subject and the first opening and receiving light from a front side and leading to the first opening,
The said 3rd opening part is a lens drive apparatus provided in the front side of the said lens carrier. The method of claim 1,
And a lens driving device casing on which the lens carrier is supported.
And the third opening portion enables the lens barrel to be mounted in a state where the lens carrier is supported by the lens driving device casing. The method of claim 3, wherein
The lens drive device casing surrounds the lens carrier,
And the third opening faces the lens driving device casing directly. The method of claim 4, wherein
The lens drive device casing has a cover that covers the front face thereof, and the lens drive device directly faces the third opening. The method of claim 1,
The lens carriers are two, for fixing the lens barrels in which the optical axes coincide with each other;
The two lens carriers each have the first opening, the second opening, and the third opening, and the two third openings are opened on the same side.
Lens drive device. The method of claim 6,
An optical member is further provided between the subject and the lens carrier, wherein the third openings are opened on the same side as the side on which the optical member receives light from the subject. The method of claim 1,
And the lens carrier is driven in the optical axis direction of the lens barrel. The camera device provided with the lens drive apparatus in any one of Claims 1-8, the said lens barrel, and the light receiving sensor which receives the light which passed the said lens barrel. An electronic apparatus provided with the camera apparatus of Claim 9.

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