JP6439213B2 - Multilayer coil, lens driving device, camera device and electronic device - Google Patents

Description

  The present invention relates to a laminated coil, a lens driving device, a camera device, and an electronic apparatus.

  Electronic devices such as mobile phones and smartphones are equipped with small cameras. Some small cameras of this type perform camera shake correction. A small camera that performs camera shake correction is provided with a lens driving device that drives a lens.

  In camera shake correction, there is a method in which a moving body including a lens holding body provided in a lens driving device is moved in a direction orthogonal to the optical axis direction. In such a lens driving device, a magnet and a coil are used to move the moving body.

  In general electronic devices, as disclosed in Patent Document 1, a multilayer coil is known in which a printed coil is formed in each of a plurality of layers and the printed coils are connected to each other through through holes.

Japanese Patent Application Laid-Open No. 2014-232728

  For example, when a laminated coil is used in the lens driving device, increasing the number of laminated layers improves the thrust for moving the moving body, while increasing the thickness in the laminated direction. For this reason, it is necessary to design the number of layers in consideration of the balance between thrust and thickness.

  However, conventionally, the number of laminated coils is generally an even number, and it has not been easy to make an odd number of laminated coils. The reason for this is that when the terminal portion connected to the external wiring is provided outside the coil, if it is an even layer, for example, “the terminal portion of the external wiring → the first coil winding start (outside) → the first coil There is no problem because the winding end (inner) → the second layer coil winding start (inner) → second layer winding end (outer) → terminal portion of external wiring ”can be used. However, in the case of an odd layer, for example, “terminal portion of external wiring → first coil winding start (outside) → first layer coil winding end (inner) → second layer coil winding start (inner) → second End of winding of layer (outside) → Start of coil winding of third layer (outside) → End of winding of third layer coil (inside) ” When connecting to the wiring, there is a problem that it is necessary to get over the third layer coil, for example, it is necessary to provide one more layer.

  The present invention eliminates the above-described conventional problems, makes it possible to easily form a laminated coil composed of odd layers, and further provides a lens driving device, a camera device, and an electronic apparatus using the laminated coil. With the goal.

  One aspect of the present invention is a laminated coil, which is at least an odd number of three or more layers, a coil formed on each of the layers and wound to be elongated in one direction, and one of the layers. A first terminal connected to an inner end of the first coil in one layer at one end in the one direction, and an end in the one direction of the second coil in the second layer, which is another one of the layers. A second terminal portion provided on the outside, and a through-hole portion connecting the first terminal portion and the second terminal portion, wherein the first coil is compared with the second coil The length at one end in one direction is long.

  Preferably, the second terminal portion is connected to a wiring for supplying power to the coil.

  Preferably, the second terminal portion is connected to another coil formed outside the coil.

  Preferably, a third terminal portion connected to the inner end of the third coil in the third layer, which is another one of the layers, and a fourth terminal portion connected to the inner end of the second coil, And another through-hole portion that connects the third terminal portion and the fourth terminal portion.

  Preferably, a fifth terminal portion connected to the outer end of the first coil, and a sixth terminal portion connected to the outer end of the coil formed in one of the layers adjacent to the first layer. And another through-hole portion that connects the fifth terminal portion and the sixth terminal portion.

  Another aspect of the present invention is a lens driving device that includes the laminated coil and a magnet that faces the laminated coil in the optical axis direction, and the layers of the laminated coil are laminated in the optical axis direction.

  Another aspect of the present invention includes the lens driving device, a lens support disposed in a yoke, a lens supported by the lens support, and a light receiving sensor that receives light from the lens. It is a camera device.

  Still another embodiment of the present invention is an electronic apparatus equipped with the camera device.

  According to the present invention, the first coil is made longer than the second coil, and the first terminal connected to the inner end of the first coil and the second terminal provided outside the second coil are passed through. Since the connection is made through the hole portion, it is possible to easily form a laminated coil composed of an odd number of layers, and to provide a lens driving device, a camera device, and an electronic apparatus using the laminated coil.

It is a disassembled perspective view which shows the lens drive device which concerns on 1st embodiment of this invention. It is the perspective view which showed the lens drive device which concerns on 1st embodiment of this invention, and excluded the shield case. The lens drive device which concerns on 1st embodiment of this invention is shown, and it is the sectional view on the AA line of FIG. The lens drive device which concerns on 1st embodiment of this invention is shown, and it is the BB sectional drawing of FIG. It is a top view which shows the laminated coil which concerns on 1st embodiment of this invention. It is a top view which shows the laminated coil which concerns on 2nd embodiment of this invention. It is a top view which shows the Example comprised based on the laminated coil which concerns on 1st embodiment and 2nd embodiment of this invention.

Embodiments of the present invention will be described with reference to the drawings.
First, an outline of the lens driving device will be described.
1 to 4 show a lens driving device 10 according to a first embodiment of the present invention.
As best shown in FIG. 1, the lens driving device 10 includes a shield case 12, an upper spring member 14, a magnet holder 16, a yoke 18, a magnet 20, a lens support 22, an optical axis direction driving coil 24, and a lower spring member. 26, a support wire 28, a printed coil substrate 30, a wiring substrate 32, and a base 34.
In this specification, for the sake of convenience, one of the lens driving devices 10 in the optical axis direction is referred to as an upper side and the other is referred to as a lower side.

  The shield case 12 is made of, for example, a non-magnetic material such as stainless steel, and has an outer shape viewed from above formed in a square shape, and is provided with a circular first hole 36, and light is transmitted through the first hole 36. Pass through. The periphery of the lens driving device 10 is covered by the shield case 12 and the base 34 attached to the lower part of the shield case 12.

  As shown best in FIG. 2, the upper spring member 14 is divided into two parts, which are a magnet holder side fixing portion 38, a lens support side fixing portion 40, a magnet holder side fixing portion 38, and a lens support side fixing. And an elastic arm portion 42 that connects the portion 40. The upper spring member 14 has a support wire fixing portion 44 that protrudes annularly from the magnet holder side fixing portion 38 toward the outside. The magnet holder side fixing portions 38 are fitted to the magnet holder side protrusions 46 formed on the magnet holder 16 at four corners of the magnet holder 16 and fixed via an adhesive or the like. A lens support-side protrusion 48 is formed on the upper surface of the lens support 22, and the lens support-side fixing portion 40 is fitted to the lens support-side protrusion 48 and fixed via an adhesive or the like. The elastic arm portion 42 extends from the vicinity of the magnet holder side protrusion 46 of the magnet holder side fixing portion 38 toward the lens support side protrusion portion 48 while meandering to the adjacent corner, and the lens support of the lens support side fixing portion 40 is supported by the lens. It is connected in the vicinity of the body side protrusion 48.

  The yoke 18 is a magnetic body and is formed in a square shape when viewed from above, and the upper end of the yoke 18 is fixed to the magnet holder 16 with an adhesive or the like. The magnet 20 is composed of four rectangular parallelepiped pieces, and is fixed to the lower surfaces of the four sides of the magnet holder 16. The outer surface of the magnet 20 is fixed to the inner surface of the yoke 18 with an adhesive or the like.

  The lens support 22 includes a cylindrical support main body 50, a plurality of coil fixing portions 52 protruding outward from the outer peripheral surface of the support main body 50, and a flange protruding in a flange shape from the outer peripheral surface of the support main body 50. Part 54. For example, a screw is formed inside the support main body 50, and a lens (not shown) is screwed.

  The optical axis direction driving coil 24 is formed as a quadrangular frame by winding a core wire such as copper. The optical axis direction driving coil 24 is in contact with the lower surface of the flange portion 54 of the lens support 22 and the outer surface of the coil fixing portion 52 and is fixed to the lens support 22. The outer surface of the optical axis direction driving coil 24 faces each inner surface of the magnet 20. One end of the optical axis direction driving coil 24 is electrically connected to one of the upper spring members 14 divided into two parts, and the other end is electrically connected to the other of the upper spring members 14.

  The lower spring member 26 has the same configuration as the upper spring member 14, and connects the magnet holder side fixing portion 56, the lens support side fixing portion 58, the magnet holder side fixing portion 56, and the lens support side fixing portion 58. And an elastic arm portion 60. The magnet holder side fixing portion 56 is fixed to the lower four corners of the magnet holder 16 with an adhesive or the like. The lens support side fixing portion 58 is fixed to the lower surface of the lens support 22 via an adhesive or the like. The lens support 22 is sandwiched between the upper spring member 14 and the lower spring member 26 in the vertical direction, and is supported so as to be movable up and down with respect to the magnet holder 16.

  The printed coil substrate 30 is formed as a rectangular frame, and laminated coils 62 are provided on the four sides of the printed coil substrate, respectively. The laminated coil 62 faces the lower surface of the magnet 20 and constitutes an actuator for camera shake correction together with the yoke 18 and the magnet 20.

  An external connection terminal 64 is formed on the wiring board 32 so as to protrude downward on one side of the wiring board 32. The external terminal 64 is exposed to the outside through an external terminal recess 66 formed in the shield case 12.

  The base 34 is fixed below the shield case 12 and inside the shield case 12. The base 34 is provided with a circular second hole 68, and light passes through the second hole 68.

  A wiring board 32 is fixed above the base 34, and a printed coil board 30 is further fixed above the wiring board 32.

  The upper spring member 14, the magnet holder 16, the yoke 18, the magnet 20, the lens support 22, the optical axis direction driving coil 24, and the lower spring member 26 constitute one moving body 70. The moving body 70 is supported by four support wires 28 at the four corners of the moving body 70.

  That is, the support wire 28 is composed of an elastically deformable thin wire, and as shown in FIGS. 2 and 4, one end of the support wire 28 is fixed to the wiring board 32 and the other end is the support wire of the upper spring member 14. It is fixed to the fixing portion 44. Since the support wire 28 can be elastically deformed, it supports the moving body 70 so that the moving body 70 can move in parallel in a direction orthogonal to the optical axis direction.

  Two of the support wires 28 also serve as wiring. That is, the current for adjusting the optical axis direction that has entered from the external connection terminal 64 of the wiring board 32 passes through one of the upper spring members 14 divided into two parts via one of the support wires 28, in the optical axis direction. The current flows through the driving coil 24, and further exits from the external connection terminal 64 of the wiring board 32 via the other of the upper spring member 14 and the support wire 28.

  A lens is supported on the lens support 22 described above. The lens driving device 10 in which the lens is supported on the lens support 22 is mounted on the camera device. In the camera device, light input from the subject via the lens is detected by a light receiving sensor. A movement amount of the lens for focusing the subject is calculated by a controller provided in the camera. This controller controls so that a current corresponding to the moving amount of the lens flows in the optical axis direction driving coil 24. When a current flows through the optical axis direction driving coil 24, an electromagnetic force is generated in the optical axis direction driving coil 24 to move upward or downward by the magnetic flux from the magnet 20. When electromagnetic force is generated in the optical axis direction driving coil 24, the lens moves together with the coil 24 and the lens support 22 against the upper spring member 14 and the lower spring member 26, and is brought into focus.

  Further, when camera shake occurs, the displacement direction and amount are detected via a sensor (not shown), and the laminated coil 62 described in detail below is energized to generate electromagnetic force on the moving body 70, thereby It is corrected by moving it in a direction perpendicular to the optical axis direction against the elastic force.

Next, the laminated coil 62 will be described in detail.
FIG. 5 shows a first embodiment of the laminated coil 62.
The laminated coil 62 includes three or more odd-numbered layers, in this embodiment, for example, three layers 72a, 72b, and 72c.

  The first layer 72a is located at the uppermost position, the second layer 72b is located at the lowermost position, and the third layer 72c is located between the first layer 72a and the second layer 72b. The first layer 72a, the second layer 72b, and the third layer 72c are provided with, for example, a first coil 74a, a second coil 74b, and a third coil 74c that are printed. Each of the first coil 74a, the second coil 74b, and the third coil 74c includes two linear portions 76a-1, 76a-2, 76b-1, 76b-2, and 76c that extend in one direction (left and right in FIG. 5). -1,76c-2 and semicircular portions 78a-1, 78a-2, 78b-1, 78b-2, 78c-1, 78c-2 on both the left and right sides, each having about 10 turns from the inside to the outside Or wound from outside to inside.

  The second coil 74b and the third coil 74c have the same shape, while the first coil 74a is formed longer by W at both ends in one direction than the second coil 74b and the third coil 74c.

  The 1st terminal part 80a is arrange | positioned inside one semicircle part 78a-1 of the 1st coil 74a, and the inner end of the 1st coil 74a is connected. The second terminal portion 80b is disposed outside the one semicircular portion 78b-1 of the second coil 74b, and is connected to the wiring end A. The first terminal portion 80a and the second terminal portion 80b have the same position in the left-right direction, and are connected via the first through-hole portion 82a. Accordingly, the first coil 74a is longer than the second coil 74b on the side where the first terminal portion 80a is formed.

  The 3rd terminal part 80c is arrange | positioned inside one semicircle part 78c-1 of the 3rd coil 74c, and the inner end of the 3rd coil 74c is connected. The fourth terminal portion 80d is disposed inside one semicircular portion 78b-1 of the second coil 74b, and the inner end of the second coil 74b is connected thereto. The third terminal portion 80c and the fourth terminal portion 80d have the same position in the left-right direction, and are connected via the second through-hole portion 82b. That is, at the third terminal portion 80c and the fourth terminal portion 80d, the inner ends of the third coil 74c and the second coil 74b are connected to each other.

  The fifth terminal portion 80e is disposed outside the other semicircular portion 78a-2 of the first coil 74a, and the outer end of the first coil 74a is connected thereto. The sixth terminal portion 80f is disposed outside the other semicircular portion 78c-2 of the third coil 74c adjacent to the first coil 74a in the stacking direction, and is connected to the outer end of the third coil 74c. The fifth terminal portion 80e and the sixth terminal portion 80f have the same position in the left-right direction, and are connected via the third through-hole portion 82c. That is, at the fifth terminal portion 80e and the sixth terminal portion 80f, the outer ends of the first coil 74a and the third coil 74c are connected to each other.

  The seventh terminal portion 80g is disposed outside the one semicircular portion 78b-1 of the second coil 74b, and is connected to the outer end of the second coil 74b and the wiring end B. For example, a power source for supplying power to the coils 74a to 74c may be connected to the wiring end A and the wiring end B, or other coils formed outside the coils 74a to 74c as shown in the embodiments described later. May be connected.

  In the above configuration, the current that has entered the second terminal portion 80b from the wiring end A flows to the first terminal portion 80a via the first through-hole portion 82a, and clockwise from the inside to the outside of the first coil 74a. Flowing. The current that flows from the first coil 74a to the fifth terminal portion 80e flows to the sixth terminal portion 80f via the third through-hole portion 82c, and further flows clockwise from the outside to the inside of the third coil 74c. The current that flows from the third coil 74c to the third terminal portion 80c flows to the fourth terminal portion 80d via the second through-hole portion 82b, and further flows clockwise from the inside to the outside of the second coil 74b. Then, the current flowing through the second coil 74b goes out to the wiring end B through the seventh terminal 80g.

As indicated by the arrows in FIG. 5, currents that coincide in the clockwise direction flow through the first coil 74 a, the second coil 74 b, and the third coil 74 c, so that thrust corresponding to the total number of turns is applied. It can act on the moving body 70.
The first coil 74a is formed longer by W at both ends than the second coil 74b and the third coil 74c. This is for maintaining the balance of thrust, and the first terminal portion 80a and Only one side on which the second terminal portion 80b is formed may be formed long.

  Thus, in the present embodiment, the first coil 74a is made longer than the second coil 74b, and the first terminal portion 80a inside the first coil 74a and the second terminal portion 80b outside the second coil 74b, Are connected via the first through-hole portion 82a, the number of layers can be made odd.

FIG. 6 shows a second embodiment of the laminated coil 62.
The laminated coil 62 includes a first layer 72a, a second layer 72b laminated under the first layer 72a, and a third layer 72c laminated under the second layer 72b. The first layer 72a, the second layer 72b, and the third layer 72c are provided with, for example, a first coil 74a, a second coil 74b, and a third coil 74c that are printed. Each of the first coil 74a, the second coil 74b, and the third coil 74c includes two linear portions 76a-1, 76a-2, 76b-1, 76b-2, and 76c that extend in one direction (left and right in FIG. 6). -1,76c-2, left semicircular portions 78a, 78b, 78c, and right straight connecting portions 84a, 84b, 84c, each having about 10 turns from the inside to the outside, or from the outside to the inside It is wound around.

  The second coil 74b and the third coil 74c have the same shape, while the first coil 74a is provided with a first terminal portion 80a and a second terminal portion 80b as compared with the second coil 74b and the third coil 74c. It is formed longer by W at the left end in one direction.

  The 1st terminal part 80a is arrange | positioned inside the semicircle part 78a of the 1st coil 74a, and the inner end of the 1st coil 74a is connected. The second terminal portion 80b is disposed outside the semicircular portion 78b of the second coil 74b and is connected to the wiring end B. The first terminal portion 80a and the second terminal portion 80b have the same position in the left-right direction, and are connected via the first through-hole portion 82a.

  The third terminal portion 80c is disposed inside the semicircular portion 78c of the third coil 74c, and the inner end of the third coil 74c is connected thereto. The fourth terminal portion 80d is disposed inside the semicircular portion 78b of the second coil 74b, and the inner end of the second coil 74b is connected thereto. The third terminal portion 80c and the fourth terminal portion 80d have the same position in the left-right direction, and are connected via the second through-hole portion 82b. That is, at the third terminal portion 80c and the fourth terminal portion 80d, the inner ends of the third coil 74c and the second coil 74b are connected to each other.

  The fifth terminal portion 80e is disposed outside the semicircular portion 78a of the first coil 74a and is connected to the outer end of the first coil 74a. The sixth terminal portion 80f is disposed outside the semicircular portion 78b of the second coil 74b adjacent to the first coil 74a in the stacking direction, and is connected to the outer end of the second coil 74b. The fifth terminal portion 80e and the sixth terminal portion 80f have the same position in the left-right direction, and are connected via the third through-hole portion 82c. That is, at the fifth terminal portion 80e and the sixth terminal portion 80f, the outer ends of the first coil 74a and the second coil 74b are connected to each other.

  The seventh terminal portion 80g is disposed outside the semicircular portion 78 of the third coil 74c, and is connected to the outer end of the third coil 74c and the wiring end A. For example, a power source for supplying power to the coils 74a to 74c may be connected to the wiring end A and the wiring end B, or other coils formed outside the coils 74a to 74c as shown in the embodiments described later. May be connected.

  In the above configuration, the current that has entered the seventh terminal portion 80g from the wiring end A flows in the clockwise direction from the outside to the inside of the third coil 74c. The current that flows from the third coil 74c to the third terminal portion 80c flows to the fourth terminal portion 80d through the second through-hole portion 82b, and flows in the clockwise direction from the inside to the outside of the second coil 74b. The current that flows from the second coil 74b to the sixth terminal portion 80f flows to the fifth terminal portion 80e via the third through-hole portion 82c, and further flows clockwise from the outside to the inside of the first coil 74a. The current that flows from the first coil 74a to the first terminal portion 80a flows to the second terminal portion 80b through the first through-hole portion 82a and goes out to the wiring end B.

  Also in this embodiment, the first coil 74a is made longer than the second coil 74b on the side where the first terminal portion 80a is formed, and the first terminal located inside the first coil 74a, as in the above-described embodiment. Since the portion 80a and the second terminal portion 80b outside the second coil 74b are connected via the first through-hole portion 82a, the number of layers can be made odd.

  As is clear from the above description, the coil formed in one layer is made longer than the coil in the other layer, and the terminal portion arranged inside the coil in one layer and the outside of the coil in the other layer are arranged. An odd-numbered layer laminated coil can be realized by connecting the arranged terminal part via a through-hole part.

FIG. 7 shows an embodiment of a laminated coil 62 according to the present invention.
The laminated coil 62 includes an A series arranged on the left and right in the drawing and a B series arranged on the top and bottom.

  In the first layer 72a, A-series first coils 74A-a-1, 2, 3 and B-series first coils 74B-a-1, 2, 3 are arranged, and in the second layer 72b, A-series coils A A series second coil 74A-b-1,2,3 and a B series second coil 74B-b-1,2,3 are arranged, and the third layer 72c has an A series third coil 74A-c. -1,2,3 and B series first coils 74B-c-1,2,3 are arranged.

  In addition, between the first coils 74A-a-2 and 74A-a-3 and 74B-a-2 and 74B-a-3, respectively, the second coils 74A-b-2 and 74A-b-3 and 74B. -B-2 and 74B-b-3, respectively, and between the third coils 74A-c-2 and 74A-c-3 and 74B-c-2 and 74B-c-3, respectively. A position detecting element such as a Hall element is arranged so that the influence of the coil current can be reduced to detect the position of the magnet 20 described above.

The first coils 74A-a-1,2,3,74B-a-1,2,3 are the second coil coils 74A-b-1,2,3,74B-b-1,2,3 and the third coil The length in one direction is longer than that of the coils 74A-c-1,2,3,74B-c-1,2,3.
That is, a set of a first coil 74A-a-1, a second coil 74A-b-1, a third coil 74A-c-1, a first coil 74B-a-1, a second coil 74B-b-1, A set of third coils 74B-c-1 corresponds to the first embodiment described above, and a set of first coils 74A-a-2, second coils 74A-b-2, and third coils 74A-c-2. A set of a first coil 74A-a-3, a second coil 74A-b-3, a third coil 74A-c-3, a first coil 74B-a-2, a second coil 74B-b-2, The set of the third coil 74B-c-2 and the set of the first coil 74B-a-3, the second coil 74B-b-3, and the third coil 74B-c-3 are respectively described in the second embodiment. Applicable.

  In the A series, the current that has entered from the terminal portion AS flows from A1 to A18 according to the order and exits from the terminal portion AE. In the B series, the current that has entered from the terminal portion BS flows up to B26 in the order and exits from the terminal portion BE. When current flows in the A series, the above-described moving body moves to the left and right in FIG. 7, and when current flows in the B series, it moves up and down.

  It should be noted here that the terminal portions A5 and A6, A7 and A8, A13 and A14, the terminal portions B9 and B10, B19 and B20, and B21 and B22. These terminal portions connect the inside of the coil in one layer and the outside of the coil in the other layer through a through-hole portion, thereby forming a laminated coil 62 having three layers.

  In the above embodiments and examples, the laminated coil is composed of three layers, but any number of layers may be used as long as it is an odd number. In this specification, the laminated coil used in the lens driving device has been described. However, the laminated coil can be used in other devices and devices.

DESCRIPTION OF SYMBOLS 10 Lens drive device 12 Shield case 14 Upper spring member 16 Magnet holder 18 Yoke 20 Magnet 22 Lens support body 24 Optical axis direction drive coil 26 Lower spring member 28 Support wire 30 Print coil substrate 32 Wiring substrate 34 Base 62 Multilayer coil 72a 72c layer 74a-74c coil 80a-80g terminal part 82a-82c through hole part

Claims (8)

An odd number of layers of at least 3 and
A coil formed in each of the layers and wound to be elongated in one direction;
A first terminal connected to one end of the one direction on the inner end of the first coil in the first layer, which is one of the layers;
A second terminal portion provided on the outer side of one end side in the one direction of the second coil in the second layer which is the other one of the layers;
A through-hole portion connecting the first terminal portion and the second terminal portion,
The first coil is a laminated coil having a longer length on one end side in the one direction than the second coil.   The laminated coil according to claim 1, wherein the second terminal portion is connected to a wiring that supplies power to the coil.   The laminated coil according to claim 1, wherein the second terminal portion is connected to another coil formed outside the coil.   A third terminal connected to the inner end of the third coil in the third layer, which is another one of the layers, a fourth terminal connected to the inner end of the second coil, and the third The multilayer coil according to claim 1, further comprising: a through hole portion that connects the terminal portion and the fourth terminal portion.   A fifth terminal connected to the outer end of the first coil; a sixth terminal connected to the outer end of the coil formed in one of the layers adjacent to the first layer; The multilayer coil according to claim 4, further comprising another through-hole portion that connects a five-terminal portion and the sixth terminal portion.   6. A lens driving device comprising: the laminated coil according to claim 1; and a magnet facing the laminated coil in the optical axis direction, wherein the layers of the laminated coil are laminated in the optical axis direction. 7. A camera device comprising: the lens driving device according to claim 6; a lens support disposed in the magnet; a lens supported by the lens support; and a light receiving sensor that receives light from the lens. An electronic apparatus comprising the camera device according to claim 7.

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