JP2008129597A - Focusing structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a focusing structure capable of easily adjusting the position of a lens and accurately adjusting a focus. <P>SOLUTION: An external thread is formed on the external wall of the lens. An internal thread is formed on the internal wall of a rotor. An internal thread capable of engaging with the external thread of the lens is formed on the internal wall of a lens barrel. The action of the engagement of the lens barrel and lens moves this lens. An external thread capable of engaging with the internal thread of the rotor is formed on the external wall of the lens barrel. The action of the engagement of the lens barrel and rotor drives so as to adjust the focus. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a focus adjustment structure, and more particularly to a focus adjustment structure applied to an electronic product with a camera.

  With the development of science and technology and modernized industry, electronic products such as digital cameras and camera-equipped mobile phones are widely used by users. In such electronic products, there is an increasing interest in contractors for focus adjustment structures.

  The two-stage focus adjustment structure used in electronic products adjusts the focus while reciprocating the lens between the far focus and the near focus. The structure of the two-stage focus adjustment lens includes a hollow cylindrical lens barrel and a lens mounted inside the lens barrel. Permanent magnets are installed on the outer peripheral surface of the lens barrel, and coils are arranged on both sides of the permanent magnet. When currents having different directions flow through the two coils, one coil and the permanent magnet attract each other, and the other one coil and the permanent magnet repel each other, so that the lens barrel and the lens are distant from each other. Move between focus and near focus. Thereby, two-stage focus adjustment is realized.

  However, in the two-stage focus adjustment structure, when the lens is mounted on the lens barrel, the lens position cannot be adjusted again, so that the lens cannot be accurately mounted on the lens barrel. In the two-stage focus adjustment structure, since the lens is moved between the two focal points, the focal point cannot be adjusted accurately.

  In view of the above problems, an object of the present invention is to provide a focus adjustment structure that can easily adjust the position of a lens and accurately adjust the focus.

  A focus adjustment structure according to the present invention includes a stator, a rotor disposed inside the stator, a lens barrel accommodated inside the rotor, and a lens mounted inside the lens barrel. In the adjusting structure, an external thread is formed on the outer wall of the lens, an internal thread is formed on the inner wall of the rotor, and an internal thread that engages the external thread of the lens on the inner wall of the barrel A crest is formed, and the lens barrel is moved by the action of engaging the lens, and an outer thread that engages the inner thread of the rotor is formed on the outer wall of the barrel. The focus is adjusted by the action of engagement between the lens barrel and the rotor.

  Further, the focus adjustment structure according to the present invention is a focus adjustment structure including a frame, a stepping motor accommodated in the frame, a lens barrel accommodated in the stepping motor, a lens, and a cover. Each of the stepping motor and the lens barrel is formed with a drive thread structure that engages with each other, and the lens is mounted inside the lens barrel, and between the lens barrel and the lens, An arrangement thread structure for engaging is formed, the cover is installed at the upper end of the lens, and a guide structure for limiting the rotation of the lens barrel is provided between the lens barrel and the cover, The tube and the lens are engaged with each other by the arrangement screw thread structure, and the stepping motor drives the lens barrel and the lens by the drive screw thread structure to guide the guide structure. Wherein the moving in the axial direction by the action that.

  In the present invention, in the focus adjustment structure, the lens barrel is provided with an external thread and an internal thread. Therefore, the position of the lens barrel and the lens is adjusted until the focused image is detected by the image sensor due to the engagement of the internal thread of the rotor and the external thread of the lens barrel. Can be adjusted automatically. Further, when the lens is fixed and the lens is assembled, the position of the lens can be slightly adjusted by the action of engagement of the internal thread of the lens barrel and the external thread of the lens. Therefore, the assembly becomes easy, the cost is reduced, and the problem of adjusting the lens assembly and the problem of the resolution of the formed image can be effectively solved.

  Hereinafter, the focus adjustment structure of the present invention will be described in detail with reference to the drawings.

As shown in FIGS. 1 to 5, the focus adjustment structure of the present invention includes a circuit board 11, a base 17 provided on the circuit board 11, a motor 12 accommodated inside the base 17, It includes a lens barrel 14 installed inside the motor 12, a lens 15 engaged inside the lens barrel 14, and a cover 16 provided at the upper end of the lens 15.
The motor 12 is a stepping motor, and includes a stator module 120 and a rotor 130 disposed inside the stator module 120.
The lens barrel 14 is disposed inside the rotor 130 of the motor 12.

  The circuit board 11 is provided with a sensor 112 electrically connected to the circuit board 11. The sensor 112 is formed of a CCD image sensor (Charge Coupled Device, CCD), a Cmos image sensor (Complementary Metal-Oxide Semiconductor, CMOS), or the like. When adjusting the focus with the focus adjustment structure, the circuit board 11 detects the image quality of the sensor 112 and adjusts the current supplied to the motor 12 based on the detected image, thereby realizing the focus adjustment.

The base 17 is disposed on the circuit board 11. The base 17 includes a substrate 171 having a rectangular outer shape and a circular opening formed therein, a frame body 172 formed by extending vertically upward from a peripheral edge of the substrate 171, and the substrate And a support portion 173 mounted on the inner side of the base 17 so as to be positioned on the upper surface 171.
As shown in FIG. 2, the frame body 172 has a rectangular outer shape and a circular opening formed therein. Four openings 175 are formed at the four corners of the frame 172 as outer shells of the focus adjustment structure. Four receiving portions 176 corresponding to the openings 175 are formed at the four corners of the substrate 171.

The support part 173 includes an annular base 177 and four support ribs 178 formed to extend outward from the base 177.
The support ribs 178 are formed corresponding to the receiving portions 176, respectively.
The base 177 includes an annular projecting portion 179 projecting upward, an inner edge convex portion 180 formed extending from the inner edge of the bottom end, and an outer edge convex portion extending outward from the outer edge of the bottom end. 181.
The projecting portion 179, the inner edge convex portion 180, and the outer edge convex portion 181 support the rotor 130, the lens barrel 14, and the stator module 120, respectively.
The outer diameter of the base 177 is slightly smaller than the inner diameter of the frame body 172. The base 177 is installed inside the frame body 172, and the support rib 178 protrudes radially outward through the opening 175 of the frame body 172 and is fitted into the receiving portion 176 of the substrate 171. . That is, the support portion 173 is fixed to the base 17 so as not to rotate. In addition, the support portion 173, the substrate 171 and the frame body 172 can be integrally formed.

The stator module 120 is installed inside the base 17 and includes a stator outer cylinder 121 and a stator 122 installed inside the stator outer cylinder 121.
The stator outer cylinder 121 is formed in a cylindrical shape, and two slits 123 corresponding to the opening 175 of the base 17 are formed from the axial center to the lower end.
The stator 122 is formed in a cylindrical shape, and a columnar space for accommodating the rotor 130 is formed therein. A plurality of pole pieces 124 for determining the rotation angle of the stepping motor are provided on the inner wall of the stator 122. A coil 125 is wound around the outer wall of the stator 122 along the axial direction (shown in FIG. 5). The lower end of the coil 125 passes through the slit 123 of the stator outer cylinder 121 and the opening 175 of the base 17 and is wound around the support rib 178. Thereby, the coil 125 and the circuit board 11 are easily electrically connected.

The rotor 130 is accommodated in the columnar space of the stator 122 and includes an annular columnar permanent magnet 131.
The permanent magnet 131 is formed of ferrite (ferrite), neodymium iron boron (NdFeB), or the like, and is installed on the base 177 of the support portion 173.
A magnet ring 133 is disposed at one end of the permanent magnet 131 adjacent to the base 177.
As shown in FIG. 3, the magnet ring 133 is formed in a hollow annular shape, and a stepped portion 134 is formed on the outer wall at the upper end. The bottom end of the permanent magnet 131 is attached to the stepped portion 134, and the magnet ring 133 and the permanent magnet 131 are integrally fixed. An inner thread 136 for moving the lens 15 is formed on the inner wall of the magnet ring 133.
An annular protective layer 138 made of a material that is not easily worn out is attached to one end of the permanent magnet 131 adjacent to the cover 16. The protective layer 138 prevents the cover 16 from being worn when the permanent magnet 131 rotates.

  The lens barrel 14 is disposed inside the permanent magnet 131 and is formed in a cylindrical shape whose outer diameter is slightly smaller than the inner diameter of the permanent magnet 131. The upper end and the lower end of the lens barrel 14 project outside the permanent magnet 131 along the axial direction when the lens barrel 14 is mounted inside the permanent magnet 131. A plurality of recesses 143 are formed at the upper end of the lens barrel 14 adjacent to the cover 16 so as to be separated from each other along the circumferential direction. The lower end portion of the lens barrel 14 is installed on the inner edge convex portion 180 of the support portion 173. An outer thread 146 that engages with the inner thread 136 of the magnet ring 133 and moves the lens 15 is formed at the lower end of the outer wall of the lens barrel 14. An inner thread 148 for mounting the lens 15 is formed at the lower end of the inner wall of the lens barrel 14.

  The lens 15 is formed in a columnar shape, and is mounted on the inner side of the lens barrel 14, and an outer thread 158 that engages with the inner thread 148 of the lens barrel 14 is formed on the outer wall. When the lens 15 is mounted inside the lens barrel 14, the position of the lens 15 can be adjusted by the action of the internal thread 148 and the external thread 158 engaging.

The cover 16 is an annular body that is disposed at the upper end of the lens 15 and has an inner diameter that is substantially the same as the outer diameter of the lens 15. An annular convex portion 162 is integrally formed in the central portion of the cover 16 along the circumferential direction. The annular protrusion 162 is pressed against the protective layer 138 of the permanent magnet 131 of the rotor 130 to prevent the permanent magnet 131 from moving along the axis.
A plurality of guides 163 are formed on the inner edge of the cover 16 so as to be separated from each other along the circumferential direction. The guide portion 163 is engaged with the concave portion 143 of the lens barrel 14 to prevent the lens barrel 14 and the lens 15 from rotating along the circumferential direction. Therefore, the lens 15 is placed at an accurate position and is prevented from swinging.

  When assembling the focus adjustment structure of the present invention, first, the lens 15 is mounted on the inside of the lens barrel 14 so that the external thread 158 of the lens 15 engages the internal thread 148 of the lens barrel 14. . Thus, the position of the lens 15 is accurately adjusted by the thread structure engaged with each other. Next, the external thread 146 of the lens barrel 14 and the internal thread 136 of the rotor 130 are engaged with each other, and the lens 15 is moved along the axial direction by the engaging action of the threads. The lens barrel 14 is mounted inside the rotor 130. Next, the rotor 130 is mounted inside the stator 122 of the stator module 120, and the stator module 120 is mounted inside the base 17. Thereby, the stator 122, the magnet ring 133, and the lens barrel 14 are connected to the outer edge convex portion 181 of the support portion 173, the protruding portion 179, and the inner edge convex portion 180, respectively. Next, the cover 16 is attached to the upper end of the lens barrel 14. As a result, the annular convex portion 162 of the cover 16 is pressed against the protective layer 138 of the permanent magnet 131 of the rotor 130, and the guide portion 163 is engaged with the concave portion 143 of the lens barrel 14. Finally, the base 17 is disposed on the circuit board 11.

  As shown in FIG. 6, when the coil 125 of the stator module 120 is energized, the rotor 130 rotates about the axis as a rotation axis by the magnetic field action of the coil 125 and the rotor 130. Since the magnet ring 133 of the rotor 130 is engaged with the external thread 146 of the lens barrel 14 and the rotor 130 is pressed against the cover 16, the lens barrel 14 and the lens 15 are aligned in the axial direction. The upper ends of the lens barrel 14 and the lens 15 can go out of the upper end of the cover 16. At this time, when the image quality of the sensor 112 is detected and the current of the coil 125 is adjusted via the circuit board 11 and the rotation angle of the motor 12 is adjusted, an automatic focus adjustment function can be realized. it can.

  In the focus adjustment structure, the lens barrel 14 is provided with an external thread 146 and an internal thread 148. Then, until the focused image is detected by the sensor 112 due to the engagement of the internal thread 136 of the rotor 130 and the external thread 146 of the lens barrel 14, the lens 14 and the lens 15 The position can be adjusted and the focus can be adjusted automatically. Further, when the lens 15 is assembled by assembling the inner thread 148 of the lens barrel 14 and the outer thread 158 of the lens 15, the position of the lens 15 is finely adjusted. can do. Therefore, the assembly becomes easy, the cost is reduced, and the problem of adjusting the lens assembly and the problem of the resolution of the formed image can be effectively solved.

It is a disassembled perspective view of one Embodiment of the focus adjustment structure of this invention. It is a disassembled perspective view of the base of the focus adjustment structure shown in FIG. FIG. 2 is a partial cross-sectional perspective view of a rotor and a lens barrel of the focus adjustment structure shown in FIG. It is a perspective view which shows the state by which the focusing structure shown in FIG. 1 was assembled in three dimensions. It is sectional drawing of the focus adjustment structure shown in FIG. It is sectional drawing of the work state of the focus adjustment structure shown in FIG.

Explanation of symbols

11 circuit board 12 motor 14 lens barrel 15 lens 16 cover 17 base 112 sensor 120 stator module 121 stator outer cylinder 122 stator 123 slit 124 pole piece 125 coil 130 rotor 131 permanent magnet 133 magnet ring 134 stepped portion 136 internal thread 146 external screw Thread 148 Internal thread 158 External thread 138 Protective layer 143 Concave part 162 Annular convex part 163 Guide part 171 Substrate 172 Frame 173 Support part 175 Opening 176 Receiving part 177 Base rib 179 Protrusion part 180 Inner edge convex part 181 Outer edge convex part

Claims (13)

In a focus adjustment structure including a stator, a rotor disposed inside the stator, a lens barrel accommodated inside the rotor, and a lens mounted inside the lens barrel,
External threads are formed on the outer wall of the lens,
Internal threads are formed on the inner wall of the rotor,
On the inner wall of the barrel is formed an internal thread that engages the external thread of the lens,
Due to the action of the lens barrel and the lens engaging, the lens is moved,
External threads that engage with the internal threads of the rotor are formed on the outer wall of the barrel,
A focus adjustment structure, wherein the focus is adjusted by an action of engagement between the lens barrel and the rotor. A cover disposed on an upper end of the lens;
A plurality of guide portions are provided at equal intervals along the circumferential direction on the inner edge of the cover,
The focus adjustment structure according to claim 1, wherein a plurality of concave portions that engage with the guide portion are formed at an upper end of the lens barrel. The cover is formed with an annular convex portion projecting downward from the center portion,
The focus adjustment structure according to claim 2, wherein the annular convex portion is pressed against the rotor. The rotor includes a permanent magnet and a magnet ring provided at one end of the permanent magnet,
The focus adjustment structure according to claim 1, wherein the internal thread of the rotor is provided on an inner wall of the magnet ring. The other end of the permanent magnet is provided with a protective layer,
The focus adjustment structure of claim 4, wherein the protective layer is made of a material that is not easily abraded. The stator further includes a base that supports the rotor,
The base includes a substrate, a frame formed by extending upward from the substrate, and a support portion provided inside the frame,
The focus adjustment structure according to claim 1, wherein the stator and the rotor are disposed on the support portion. The frame is cylindrical, has openings at four corners, and has receiving portions formed at locations corresponding to the openings at the four corners of the substrate,
The support portion includes an annular base body and a plurality of support ribs formed extending outward from the outer edge of the base body,
The focus adjustment structure according to claim 6, wherein the support rib is mounted inside the receiving portion corresponding to the receiving portion, and the supporting portion is fixed. The base includes an annular projecting portion projecting upward, an inner edge projecting portion formed to extend inward from an inner edge of the projecting portion, and an outer edge extending from the outer edge of the projecting portion. And an outer edge convex portion formed as
The focus adjustment structure according to claim 7, wherein the protrusion, the inner edge protrusion, and the outer edge protrusion support the rotor, the lens barrel, and the stator, respectively.   The focus adjustment structure according to claim 6, wherein the support portion, the base, and the frame are integrally formed. A circuit board,
The stator, the rotor, the lens barrel and the lens are provided on the circuit board,
The stator is electrically connected to the circuit board;
The focus adjustment structure according to claim 1, wherein a sensor that is electrically connected to the circuit board is installed on the circuit board. In a focus adjustment structure including a frame, a stepping motor accommodated in the frame, a lens barrel accommodated in the stepping motor, a lens, and a cover,
Each of the stepping motor and the lens barrel has a drive thread structure that engages with each other,
The lens is mounted inside the barrel,
Each of the lens barrel and the lens is formed with an arrangement thread structure that engages with each other.
The cover is installed at the upper end of the lens,
A guide structure is provided between the lens barrel and the cover to limit the rotation of the lens barrel.
The lens barrel and the lens are engaged with each other by the arrangement screw thread structure,
The focus adjustment structure according to claim 1, wherein the stepping motor drives the lens barrel and the lens by the structure of the drive screw thread and moves along the axial direction by an action guided by the guide structure. The guide structure includes a recess provided in the lens barrel and a guide provided in the cover,
The focus adjustment structure according to claim 11, wherein the guide portion is engaged with the concave portion. A support part is installed inside the frame,
The support part is formed by extending at least one support rib,
At least one opening is formed in the frame,
The focus adjustment structure according to claim 11, wherein the support rib is fitted into the opening.

Images