KR101043943B1 - Compact camera device - Google Patents

Abstract

The present invention is to provide a compact camera device having a simplified structure by integrating a magnet for correcting a shake and a magnet for adjusting a focus.

The compact camera device of the present invention includes a housing; A first blade which is moved up and down inside the housing and has a first coil member mounted on an outside thereof; A second blade horizontally moved inside the housing and having a second coil member mounted on an outside thereof; A magnet comprising a first magnet disposed outside the second coil member and a second magnet disposed above the first magnet outside the second coil member; A first yoke mounted below the first magnet or above the second magnet; The first blade is moved by the interaction between the first electromagnetic field generated when the power is applied to the first coil member and the magnetic field generated by the magnet, and when the power is applied to the second coil member. The second blade moves horizontally by the interaction between the generated second electromagnetic field and the magnetic field generated by the magnet, and the first yoke has a magnetic force line generated at the N pole of the magnet such that the first coil member or the second coil Induces return to S pole through member.

Camera, camera shake, york

Description

Compact camera device {

The present invention relates to a miniature camera device, and more particularly, to a miniature camera module for moving a lens up and down by using a coil and a magnet to adjust the focus of a subject and moving in a horizontal direction to compensate for hand shake.

1 is a perspective view of a conventional compact camera device, FIG. 2 is an exploded perspective view of a conventional compact camera device, and FIG. 3 is an exploded perspective view showing A of FIG.

As shown in FIGS. 1 to 3, a conventional compact camera apparatus generally includes a housing 10, a lens unit 20, a first coil 30, a first magnet 40, and an iron piece 50. Is done.

The lens unit 20 is mounted in the housing 10 to be moved in the horizontal direction.

The lens unit 20 has a lens 60 mounted therein, and functions to adjust the focus of the subject by moving the lens 60 in the optical axis direction of the lens 60.

In detail, the lens unit 20 includes a lens barrel 21 surrounding the lens 60, a holder 22 into which the lens barrel 21 is inserted, and mounted inside the holder 22. And a second coil 23 and a second coil 24 mounted on an outer side of the lens barrel 21, the electromagnetic field generated when power is applied to the second coil 24, and the second magnet. The lens barrel 21 flows in the optical axis direction of the lens 60 by the interaction of the magnetic field generated in the lens 23.

The first coil 30 is mounted to the outside of the lens unit 20.

The first coil 30 is wound in a direction rotating about the iron piece 50.

In addition, the first magnet 40 is mounted on the inner surface of the housing 10 adjacent to the first coil 30, a plurality of the first magnet 40 is in contact with the upper and lower ends of the iron piece 50, respectively.

One end of the iron piece 50 is in contact with the first magnet 40 and the other end is inserted into the center of the first coil 30 to be adjacent to the first coil 30.

By the above configuration, power is applied to the first coil 30 and the lens unit 20 is caused by the interaction between the electromagnetic field generated by the first coil 30 and the magnetic field generated by the first magnet 40. ) Moves in the horizontal direction to correct the shaking of the subject.

The conventional compact camera device has a problem in that the number of parts is increased and the size is complicated as the first magnet 40 for correcting the shake and the second magnet 23 for adjusting the focus are separately configured. have.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and provides a compact camera device in which a structure is simplified by integrating a magnet for correcting a shake and a magnet for adjusting a focus, and the shake correction and focus are easily and accurately performed. Its purpose is to.

In order to achieve the above object, the compact camera device of the present invention includes a housing; A first blade which is moved up and down inside the housing and has a first coil member mounted on an outside thereof; A second blade horizontally moved inside the housing and having a second coil member mounted on an outside thereof; A magnet comprising a first magnet disposed outside the second coil member and a second magnet disposed below the first magnet outside the second coil member; A first yoke mounted on an upper portion of the first magnet or a lower portion of the second magnet; The first blade is moved by the interaction between the first electromagnetic field generated when the power is applied to the first coil member and the magnetic field generated by the magnet, and when the power is applied to the second coil member. The second blade moves horizontally by the interaction between the generated second electromagnetic field and the magnetic field generated by the magnet, and the first yoke has a magnetic force line generated at the N pole of the magnet such that the first coil member or the second coil Induces return to S pole through member.

The first yoke protrudes in the direction of the first coil member.

The second blade is mounted to move horizontally inside the first blade, the magnet is disposed between the inner surface of the first blade and the outer surface of the second blade fixedly mounted to the housing, the first The coil member is wound around the first blade, and the second coil member is wound on the side surface of the second blade in a direction orthogonal to the winding direction of the first coil member.

The first blade is mounted to be moved up and down inside the second blade, the magnet is fixedly mounted to the housing from the outside of the second blade, the first coil member is wound around the first blade, The second coil member is wound on the side surface of the second blade in a direction orthogonal to the winding direction of the first coil member.

A second yoke mounted between the first magnet and the second magnet and inserted into a central portion of the second coil member; It further comprises, wherein the first magnet and the second magnet is disposed with the polarity up and down symmetrical around the second yoke.

The second coil member has a vertical length smaller than the sum of the vertical lengths of the magnet and the second yoke.

According to the compact camera device of the present invention as described above has the following advantages.

The first yoke is mounted on the upper side of the first magnet so that a magnetic force line generated at the north pole of the first magnet is an upper end of the first magnet via the first coil member and / or the second coil member. By returning to the S pole, the magnetic force lines generated in the magnet are prevented from being dispersed to the outside to increase the magnetic field strength of the first magnet, thereby improving the driving force of the first coil member and / or the second coil member. It is effective to let.

The first yoke protrudes toward the first coil member, thereby increasing the magnetic force line of the first magnet returned to the first magnet by bringing the first yoke close to the first coil member, thereby increasing the magnetic force line of the first magnet. The magnetic field strength of the magnet is increased to improve the driving force of the first coil member.

The second blade is mounted to be horizontally moved inside the first blade, and the magnet is disposed between the inner surface of the first blade and the outer surface of the second blade, whereby the magnetic field of the magnet is the first blade. It is delivered to both the first coil member mounted on the second coil member and the second blade member mounted on the second blade has the effect of enabling movement and horizontal movement with one magnet.

The magnetic field generated in the magnet interacts with both the first electromagnetic field and the second static magnetic field through the second yoke, thereby integrating the magnet for horizontal movement of the first blade and the horizontal movement of the second blade. It reduces the number of parts, facilitates assembly, and reduces the overall size.

The second coil member has a vertical length smaller than the sum of the vertical lengths of the magnet and the second yoke, so that the second coil member is generated in the magnet and induced by the second yoke. The amount of the magnetic field disposed within and acting on the second coil member is increased, thereby improving the lateral driving force of the second coil member.

First embodiment

4 is a perspective view of the compact camera device of the present invention, FIG. 5 is an exploded perspective view of the compact camera device of the present invention, and FIG. 6 is an enlarged partial exploded perspective view of FIG. 5D.

4 to 6, the compact camera device of the present invention includes a housing 200, a second blade 300, a second coil member 310, a first blade 400, and a first coil member 410. ), A magnet 500, a first yoke 900, a second yoke 600, a first elastic member 420, a power supply terminal 430, and a second elastic member 320.

The housing 200 is formed to be separated into the upper and lower, respectively, in a rectangular shape, the edge is projected in a direction facing each other is coupled to surround the second blade (300).

The second blade 300 is mounted to be moved horizontally inside the housing 200 in a rectangular hollow shape.

A side surface of the second blade 300 is formed with a through hole 301 opened to allow the inside and the outside of the second blade 300 to communicate with each other.

The through holes 301 are formed in one of four sides of the second blade 300 in a rectangular shape.

In addition, fixing protrusions 302 protruding in the direction of the magnet 500 are formed at both sides of the through hole 301, respectively.

The first blade 400 is mounted to move up and down inside the second blade 300.

The first blade 400 has a cylindrical hollow shape, and a plurality of lenses (not shown) for adjusting the magnification of the subject are inserted therein.

In addition, the first coil member 410 is mounted on an outer circumferential surface of the first blade 400.

The first coil member 410 is a wound around the outer peripheral surface of the first blade 400, a thin wire through which current flows.

That is, the first coil member 410 surrounds the outer circumferential surface of the first blade 400 in one direction that rotates about the optical axis of the lens.

The first coil member 410 moves up and down the first blade 400 by forming a first electromagnetic field (not shown) around when the power is applied.

Meanwhile, the second coil member 310 is mounted on the outer surface of the second blade 300.

The second coil member 310 is formed to have a hollow cylindrical shape by winding a thin wire through which a current flows inside and horizontally with an outer surface of the second blade 300.

In addition, the second coil member 310 is mounted so as to face the outer circumferential surface of the second blade 300 in pairs.

 That is, two second coil members 310 are disposed on the outer circumferential surface of the second blade 300 facing each other, one by one, and form a pair. It is mounted on the outer circumferential surface of 300).

In addition, the second coil member 310 is mounted to be inserted into the fixing protrusion 302 formed on the outer surface of the second blade (300).

That is, two fixing protrusions 302 formed at both sides of the through hole 301 are inserted into the hollow part 311 formed in the center of the second coil member 310 so that the second coil member 310 may be inserted. The hollow portion 311 is in communication with the through-hole 301.

The second coil member 310 horizontally moves the second blade 300 by forming a second electromagnetic field (not shown) around when the power is applied.

On the other hand, the magnet 500 is mounted on the side of the housing 200 is disposed adjacent to the outside of the second coil member 310.

The magnet 500 is a two-pole separate magnet up and down in a rectangular shape, and consists of a total of eight, two on each side of the housing 200.

And the magnet 500 is inserted into the insertion groove 210 formed on the side of the housing 200 is vertically separated.

The magnets 500 are installed one by one in the insertion groove 210 so that the magnets 500 are separated and disposed up and down.

In addition, the magnet 500 includes a first magnet 510 and a second magnet 520 disposed under the first magnet 510.

The second yoke 600 is mounted between the first magnet 510 and the second magnet 520.

In addition, the first magnet 510 and the second magnet 520 are disposed to have the same polarity in the direction in contact with the second yoke 600.

That is, when the lower end of the first magnet 510 disposed above the second yoke 600 is the N pole, the upper end of the second magnet 520 disposed below the second yoke 600 is also N. It becomes a pole.

As such, the magnetic fields generated by the magnet 500 are generated when the power is applied to the second coil member 310 by making the polarities of the magnet 500 in contact with the second yoke 600 the same. 2 Make it level with the electromagnetic field.

The second yoke 600 mounted between the magnets 500 may be formed of a metal material that is ferromagnetic in a rectangular shape.

Specifically, one end of the second yoke 600 is disposed between the magnets 500, and in this case, the second yoke 600 is magnetized in contact with the magnets 500.

In addition, the other end of the second yoke 600 protrudes toward the second blade 300 and penetrates through the second coil member 310 to be adjacent to the first coil member 410.

That is, the other end of the second yoke 600 is hollow of the second coil member 310 through the fixing protrusion 302 of the second blade 300 into which the second coil member 310 is inserted. It is inserted into the portion 311 and passes through the through hole 301 of the second blade 300 in communication with the hollow portion 311 is adjacent to the first coil member 410.

By inserting the second yoke 600 into the second coil member 310 as described above, the magnetic field generated by the magnet 500 passes through the second yoke 600 through the second coil member 310. ) Can be induced.

In addition, by inserting the second yoke 600 through the through hole 301 of the second blade 300, the second yoke 600 passes through the second coil member 310 and the first coil. It may be adjacent to the member 410.

On the other hand, the first yoke 900 has a rectangular shape, the thickness is thinner than the second yoke 600, the width is formed larger than the width of the magnet 500.

In addition, the first yoke 900 is formed in plural and disposed one by one on the top of the first magnet 510, and is fixedly mounted on an upper surface of the first magnet 510.

In the first embodiment, the upper end of the first magnet 510 is disposed such that the lower end of the S pole is the N pole, and the first yoke 900 is positioned on the upper end of the first magnet 510. Mounted on.

The first yoke 900 has a magnetic force line generated at the lower end of the first magnet 510 via the first coil member 410 and / or the second coil member 310. It is induced to return to the S pole, the upper end of 510.

As such, the magnetic force lines generated at the N pole of the first magnet 510 are mounted on the first magnet 510 via the first nose part 410 and / or the second coil member 310. By returning to the S pole by the first yoke (900), the magnetic force lines generated in the first magnet 510 is prevented from being dispersed to the outside to increase the magnetic field strength of the first magnet 510, thereby The driving force of the first coil member 410 and / or the second coil member 310 is improved.

Of course, in some cases, the first yoke 900 may be disposed under the second magnet 520, and may be disposed under both the upper portion of the first magnet 510 and the lower portion of the second magnet 520. It may be.

In some cases, the upper end of the first magnet 510 may be disposed such that the lower end of the N pole becomes the S pole.

In addition, the first yoke 900 protrudes in the direction of the first coil member 410.

In other words, the first yoke 900 protrudes linearly in the direction of the first coil member 410, that is, outward from the S pole of the first magnet 510, that is, the first magnet 510. The end of the protruding direction is disposed inward from the first coil member 410.

The first yoke 900 is generated at the N pole, which is the lower end of the first magnet 500, and passes the magnetic force line passing through the first coil member 410 to the S pole, which is the upper end of the first magnet 510. Encourage them to return well.

As described above, the first yoke 900 protrudes toward the first coil member 410, thereby bringing the first yoke 900 close to the first coil member 410 to the first magnet 510. The magnetic force line of the first magnet 510 is increased, and the magnetic field strength of the first magnet 510 is increased, thereby improving the driving force of the first coil member 410.

Meanwhile, the first elastic member 420 is mounted on the lower end of the first blade 400 to elastically support the first blade 400 in the vertical direction.

Specifically, the first elastic member 420 is made of a thin plate material horizontal to the second blade 300, the surface is plated with a metal material is formed so as to conduct electricity.

In addition, the first elastic member 420 has a first fixing part 421 fixed to the first blade 400, a second fixing part 422 fixed to the second blade 300 and the first height. It is formed between the government and the second fixing part is made of an elastic portion 423 that contracts or relaxes when moving up and down of the first blade (400).

The first elastic member 420 is connected to the power terminal 430 to receive power from the power terminal 430, and is also electrically connected to the first coil member 410 to the power terminal ( The power applied from 430 is transferred to the first coil member 410.

The power terminal 430 is made of a thin plate material perpendicular to the second blade 300 as opposed to the first elastic member 420.

In detail, the power terminal 430 includes a first extension part 431 formed in parallel with an outer surface of the second blade 300, and a second extension part 432 bent from the first extension part 431. )

That is, the power terminal 430 is formed in a shape in which a thin plate horizontal to the outer surface of the second blade 300 is bent along the outer surface of the second blade 300.

As described above, the power terminal 430 connected to the first elastic member 420 includes the second extension part 432 bent from the first extension part 431, and thus, the second blade 300. When the horizontal movement of the contraction or relaxation is minimized the external force applied to the second blade 300 by the power terminal 430.

Like the first blade 400, the second blade 300 is mounted with the second elastic member 320 that elastically supports the second blade 300 in the horizontal direction.

The second elastic member 320 is made of a thin long wire line, the upper end is fixed to the upper side of the housing 200, the lower end is mounted below the second blade (300).

In addition, the second elastic member 320 is made of an electrically conductive metal material, and is connected to the second coil member 310 to transfer power to the second coil member 310.

As described above, the second elastic member 320 that elastically supports the second blade 300 is connected to the second coil member 310 to transfer power to the second coil member 310, thereby transferring power separately. Supplying power to the second coil member 310 without means reduces the number of parts and facilitates assembly.

In addition, the second elastic member 320 is composed of a plurality, it is mounted on one of four places symmetrical to the second blade 300 to support the second blade 300 to maintain the horizontal.

At this time, the second elastic member 320 is connected to the second coil member 310 mounted on the outer surface of the second blade 300 to transfer power, the outer surface of the second blade 300 The same power is applied to the second coil member 310 mounted to face each other.

That is, the same power is applied to two second coil members 310 disposed on the moving line of the second blade 300 when the second blade 300 moves horizontally.

In this way, by applying the same power to the second coil member 310 mounted in pairs to face each other on the outer surface of the second blade 300, the second blade 300 when the horizontal movement of the second blade (300) The force in the same direction is added to) to improve the driving force.

According to the above configuration will be described in detail the operating state of the compact camera device of the present invention.

7 to 9 are operation state diagram of the compact camera device according to the present invention as seen from B-B of Figure 4, Figure 10 is an operating state diagram of the power supply terminal according to the present invention as seen from C-C of FIG.

As shown in FIG. 7, before the power is applied to the first coil member 410 and the second coil member 310, the first blade 400 and the second blade 300 are each of the first elastic member. Since it is supported by the member 420 and the second elastic member 320 does not move arbitrarily.

In addition, the first elastic member 420 maintains a horizontal state, and the second elastic member 320 maintains a vertical state.

8 illustrates an operating state when power is applied to the first coil member 410.

As shown in FIG. 8, when power is applied to the first coil member 410, a first electromagnetic field is formed around the first coil member 410, and the first electromagnetic field is generated in the magnet 500. By raising the first blade 400 by the interaction with the magnetic field induced through the second yoke 600.

At this time, the first yoke 900 has a magnetic force line generated at the N pole, which is the lower end of the first magnet 510, returns to the S pole, which is the upper end of the first magnet 510, through the first coil member 410. To induce.

In addition, the first blade 400 ascends and relaxes the first elastic member 420 in the upward direction.

At this time, the second blade 300 is supported by the second elastic member 320 does not rise.

On the other hand, when the direction of the power applied to the first coil member 410 is reversed, the direction of the first electromagnetic field generated by the first coil member 410 is reversed, the first blade 400 is lowered. .

At this time, the first blade 400 moves to an initial position by the elastic restoring force of the first elastic member 420, and is elastically supported so as not to be arbitrarily raised.

9 illustrates an operating state when power is applied to the second coil member 310.

As shown in FIG. 9, when power is applied to the second coil member 310, a second electromagnetic field is formed around the second coil member 310, and the second electromagnetic field is generated in the magnet 500. By horizontally moving the second blade 300 to the left side by the interaction with the magnetic field induced through the second yoke 600.

The second blade 300 is tilted by relaxing the second elastic member 320 in the left direction while moving to the left.

In addition, the first blade 400 and the first elastic member 420 mounted on the second blade 300 also move horizontally to the left side.

At this time, as shown in FIG. 10, the power terminal 430 connected to the first elastic member 420 distributes power while contracting or relaxing to minimize external force that interferes with the second blade 300.

That is, as shown in FIG. 10A, before the second blade 300 is moved, the first extension part 431 and the second extension part 432 are perpendicular to each other. As shown in FIG. 2, when the second blade 300 moves to the left side, the first extension part 431 and the second extension part 432 contract or relax with each other to distribute the force.

As described above, the magnetic field generated by the magnet 500 interacts with both the first electromagnetic field and the second electromagnetic field through the second yoke 600, thereby moving the shank east of the first blade 400. The magnet 500 for horizontal movement of the second blade 300 is integrated to reduce the number of parts, facilitate assembly, and reduce the overall size.

Second embodiment

11 is a perspective view of a compact camera device according to a second embodiment of the present invention, FIG. 12 is a one-way exploded perspective view of a compact camera device according to a second embodiment of the present invention, and FIG. 13 is a second embodiment of the present invention. Another direction exploded perspective view of the compact camera device according to the present invention.

As shown in FIGS. 4 to 7, the compact camera device according to the second embodiment of the present invention includes a housing, a first blade 1200, a first coil member 1250, a second blade 1300, and a second coil. The member 1350, the magnet 1500, the first yoke 1900, the second yoke 1600, the first elastic member 1700, and the second elastic member 1800 are formed, and the housing includes a holder ( 1100, cover 1150, and base 1400.

The holder 1100 has an hexahedral shape, the upper and lower ends of which are open, and the first blade 1200 is mounted to move upward and downward.

In addition, the first elastic member 1700 and the cover 1150 is mounted on the upper side of the holder 1100, and the base 1400 is fixed to the lower side.

The cover 1150 has a square shape and has a central portion open upward and downward to allow incident light of the lens to pass therethrough.

The first blade 1200 has a hexahedron shape, the lower end of which is opened, and an opening hole 1210 through which incident light from a lens (not shown) passes, and an upper side of the first blade member 1250 is mounted. do.

In addition, a through hole 1220 through which the first yoke 1900 is inserted is formed at an upper portion of the first blade 1200.

The through hole 1220 has a quadrangular shape, the width of which is greater than the width of the first yoke 1900, and is symmetrical with respect to the opening hole 1210.

The first coil member 1250 is a thin wire through which a current flows, and is wound around the outer surface of the first blade 1200.

At this time, the outer edge portion of the first blade 1200 is chamfered to prevent the first coil member 1250 from being damaged.

In addition, the second blade 1300 is mounted in the first blade 1200 to be moved in the horizontal direction by the second elastic member 1800.

The second blade 1300 has a hexahedron shape, the center of which is vertically open, and the lens is inserted therein.

In addition, the second coil member 1350 is mounted on a side surface of the second blade 1300.

The second coil member 1350 is a thin wire having a current flowing therein and is wound in a direction orthogonal to the winding direction of the first nose part 1250 and is formed in a circular hollow shape.

A total of four second coil members 1350 are mounted on the side surfaces of the second blade 1300 and are symmetrically disposed with respect to the optical axis of the lens.

On the other hand, the base 1400 is mounted to the lower side of the holder 100, the center is formed in the top and bottom open in a rectangular shape.

The magnet 1500, the first yoke 1900 and the second yoke 1600 are mounted and fixed to an upper side of the base 1400.

The magnet 1500 is formed of a plurality of cubes, and are arranged symmetrically with respect to the first blade 1200.

In addition, the magnet 1500 is mounted between the first blade 1200 and the second blade 1300, one surface is disposed in the direction of the first coil member 1250 and the other surface is the second coil member 1350. ) Is arranged in the direction.

That is, as shown in FIG. 14, one surface of the magnet 1500 is disposed to face the inner surface of the first blade 1200 to be mounted on the outer surface of the first blade 1200. 1250, and the other surface of the magnet 1500 is disposed to face the second coil member 1350 to be adjacent to the second coil member 1350.

As such, the magnet 1500 has one surface disposed in the direction of the first coil member 1250 and the other surface disposed in the direction of the second coil member 1350 to be mounted and fixed to the base 1400, thereby allowing the first coil to be mounted thereon. The gap between the member 1250 and the magnet 1500 is reduced, thereby simplifying the overall structure and size.

In addition, the magnet 1500 is composed of a total of eight each of two on the side of the first blade 1200, as described below, the first magnet 1510 and the first contacting the upper surface of the second yoke 1600 The second magnet 1520 is in contact with the lower surface of the two yoke 1600.

Polarities of the first magnet 1510 and the second magnet 1520 are respectively formed in the vertical direction, and the polarities of the first magnet 1510 and the second magnet 1520 are vertically symmetric with respect to the second yoke 1600.

That is, the polarity of the first magnet 1510 in contact with the upper surface of the second yoke 1600 is S pole in the upward direction, the N pole in the downward direction is disposed, the first contact with the lower surface of the second yoke 1600 The polarities of the two magnets 1520 are N poles in the upward direction and S poles in the downward direction.

The first yoke 1900 has a rectangular shape, the thickness is thinner than the second yoke 1600, and the width is wider than the width of the magnet 1500.

In addition, the first yoke 1900 may be formed in plural and disposed one by one on the top of the first magnet 1510, and may be fixedly mounted on an upper surface of the first magnet 1510.

In the present embodiment, the upper end of the first magnet 1510 is disposed so that the lower end of the S pole becomes the N pole, and the first yoke 1900 is mounted on the upper part of the S pole located at the upper end of the first magnet 1510. It was.

The first yoke 1900 has a magnetic force line generated at the lower end of the first magnet 1510 via the first coil member 1250 and / or the second coil member 1350 and the first magnet. To return to the S pole, which is the top of the 1510.

As such, the magnetic force lines generated at the N pole, which is the lower end of the first magnet 1510, are mounted on the first magnet 1510 via the first coil member 1250 or the second coil member 1350. By returning to the S pole, which is the upper end of the first magnet 1510, by the first yoke 1900, the magnetic force line generated in the first magnet 1510 is prevented from being dispersed to the outside and the first magnet 1510. Increasing the magnetic field strength, thereby improving the driving force of the first coil member 1250 and the second coil member 1350.

Of course, in some cases, the first yoke 1900 may be disposed under the second magnet 1520, and may be disposed under both the upper portion of the first magnet 1510 and the lower portion of the second magnet 1520. It may be.

In some cases, a lower end of the first magnet 1510 may be disposed such that an upper end of the S pole is an N pole.

In addition, the first yoke 1900 protrudes in the direction of the first coil member 1250.

In other words, the first yoke 1900 protrudes straight from the upper portion of the first magnet 1510 in the direction of the first coil member 1250, that is, the outward direction, and the end of the first yoke 1900 protrudes from the first coil member ( 1250).

The first yoke 1900 is generated at the N pole, which is the lower end of the first magnet 1500, so that the magnetic force line passing through the first coil member 1250 is more than the S pole which is the upper end of the first magnet 1510. Encourage them to return well.

As such, the first yoke 1900 protrudes toward the first coil member 1250, thereby bringing the first yoke 1900 into proximity with the first coil member 1250 and the first magnet 1510. To increase the magnetic force line returning to the, the magnetic field strength of the first magnet 1510 is increased, thereby improving the driving force of the first coil member 1250.

The second yoke 1600 is made of a magnetic material having a hexahedron shape, and an upper surface thereof is in contact with the first magnet 1510 and a lower surface thereof is in contact with the second magnet 1520 to be fixed to the upper side of the base 1400.

In addition, the second yoke 1600 has a total of four, one each on the side of the first blade 1200.

The second yoke 1600 is disposed between the first blade 1200 and the second blade 1300 as shown in FIG. 14, and one surface thereof is disposed in the direction of the first coil member 1250. It is adjacent to the first coil member 1250, the other surface is disposed in the direction of the second coil member 1350 and adjacent to the second coil member 1350.

As described above, the magnet 1500 is disposed to be symmetrically polarized with respect to the second yoke 1600, and the second yoke 1600 has one surface disposed in the direction of the first coil member 1250 and the other surface. By disposing in the direction of the second coil member 1350, the overall structure is simplified, and the magnetic field of the magnet 1500 is sufficiently transmitted to the first coil member 1250 and the second coil member 1350, and thus the The first blade 1200 and the second blade 1300 are smoothly moved.

In addition, the second yoke 1600 is provided with a magnetic induction protrusion 1610 protruding in the direction of the second coil member 1350 and inserted into a central portion of the second coil member 1350.

The magnetic induction protrusion 1610 is formed in a quadrangular shape smaller than the width of the second yoke 1600 and is inserted into the center of the second coil member 1350 and the inner surface of the second coil member 1350. Adjacent.

The magnetic induction protrusion 1610 induces a magnetic field generated in the magnet 1500 disposed above and below the second yoke 1600 toward the second coil member 1350.

As such, the magnet 1500 is formed by protruding the second yoke 1600 in the direction of the second coil member 1350 to insert the magnetic induction protrusion 1610 inserted into the center of the second coil member 1350. The magnetic field of the is guided well in the direction of the second coil member 1350.

In addition, the first magnet 1510, which is in contact with the top surface of the second yoke 1600, is disposed at a height similar to that of the top surface of the first blade 1200, so that the through hole is formed above the first blade 1200. It is inserted at 1220.

The through hole 1220 has a square shape and is larger than the width of the magnet 1500.

As such, the through-hole 1220 through which the magnet 1500 penetrates when the first blade 1200 moves up and down is formed on the upper side of the first blade 1200, thereby the size of the first blade 1200. Reduce and reduce the magnet 1500 to smooth the vertical movement of the first blade (1200).

In addition, the length of the second coil member 1350 in the vertical direction is smaller than the sum of the vertical lengths of the magnet 1500 and the second yoke 1600.

That is, the upper end of the second coil member 1350 is disposed below the upper end of the first magnet 1510, and the lower end of the second coil member 1350 is located above the lower end of the second magnet 1520. Is placed.

As described above, the second coil member 1350 has a vertical length smaller than the sum of the vertical lengths of the magnet 1500 and the second yoke 1600, thereby allowing the second coil member 1350 to have the magnet. The amount of the magnetic field generated at 1500 and disposed in the range of the magnetic field induced by the second yoke 1600 to act on the second coil member 1350 is increased, thereby increasing the second coil member 1350. ) Has the effect of improving the driving force.

Meanwhile, a third elastic member 1790 and the second elastic member 1800 are mounted on the second blade 1300.

The third elastic member 1790 is formed of a thin plate having a rectangular shape, the outside of which is fixed to the base 1400, and the inside of the second blade 1300 is mounted below the second blade 1300. ) Is elastically supported in the vertical direction and the horizontal direction.

The second elastic member 1800 is formed of a wire spring formed vertically long, one end is fixed to the upper end of the first blade 1200, the other end is fixed to the lower portion of the second blade 1300 The second blade 1300 is elastically supported to be moved in the horizontal direction inside the first blade 1200.

In addition, the second elastic member 1800 is made of an electrically conductive material and is electrically connected to the disconnection of the second nose part 1350.

A total of four second elastic members 1800 are mounted on the lower portion of the second blade 1300 and are symmetrically disposed with respect to the optical axis of the lens.

In addition, the first elastic member 1700 is mounted on the first blade 1200.

The first elastic member 1700 is formed of a thin plate of a rectangular shape, the outer side is fixed to the upper side of the holder 100 and the inner side is fixed to the upper side of the first blade 1200.

The outer and inner sides of the first elastic member 1700 are elastically connected to each other and can be contracted and relaxed in the vertical direction to elastically support the first blade 1200 to be moved up and down in the holder 100. .

In addition, the side of the first elastic member 1700 is bent to the side of the holder 100 is formed with a terminal portion 1750 connected to an external power source, is connected to an external power source is the first coil member 1250 And a function of supplying power to the second coil member 1350.

Specifically, the first elastic member 1700 is a conductor layer (not shown) connected to an external power source to transfer power to the first coil member 1250 and the second coil member 1350, and the conductor layer. It consists of an insulating layer surrounding the.

The conductor layer is composed of a plurality of electrical circuits for transmitting power to the first coil member 1250 or the second elastic member 1800, and is electrically connected to an external power source.

That is, the conductor layer is directly connected to the disconnection of the first coil member 1250 to transfer external power to the first coil member 1250, and is electrically connected to one end of the second elastic member 1800. Power is supplied to the second coil member 1350 connected to the other end of the second elastic member 1800.

As such, one end of the second elastic member 1800 that elastically supports the second blade 1300 in the horizontal direction is electrically connected to the conductor layer, and the other end thereof is electrically disconnected from the second coil member 1350. Connected to the second coil member 1350 by supplying external power, thereby performing both the function of supplying power and the function of elastically supporting the second blade 1300 to reduce the overall number of parts and simplify the structure Let's do it.

The insulating layer is made of a material that does not conduct electricity, and surrounds the conductor layer to prevent the conductor layer from being damaged and to block external electrical noise.

In addition, the insulating layer is made of a flexible material is easily bent and has an elastic force.

As such, the first elastic member 1700 mounted on the first blade 1200 and elastically supporting the first blade 1200 up and down is connected to an external power source so that the first coil member 1250 and the first 2 consists of a conductor layer for transmitting power to the coil member 1350 and an insulating layer surrounding the conductor layer, thereby performing both a function of supplying power and a function of elastically supporting the first blade 1200. Reduce the number and simplify the structure

The operation state of the compact camera device of the present invention according to the above configuration will be described.

FIG. 14 is a cross-sectional view of the compact camera apparatus according to the second embodiment of the present invention as seen from the EE of FIG. 11, and FIGS. 15 and 16 are views of the compact camera apparatus according to the second embodiment of the present invention to the EE of FIG. This is an operation state diagram.

As shown in FIG. 14, before power is applied to the first coil member 1250 and the second coil member 1350, the first blade 1200 may include the first elastic member 1700 and the third coil. The elastic member 1790 is disposed to be supported above the base 1400, and the first elastic member 1700 maintains a horizontal state.

In addition, the second blade 1300 is disposed in a state of being supported above the base 1400 by the second elastic member 1800 inside the first blade 1200.

In addition, the distance between the first coil member 1250 and the outer surface of the magnet 1500 is symmetrical with respect to the optical axis of the lens, the inner surface of the magnet 1500 and the second coil member 1350 The distance between the beams is symmetrical with respect to the optical axis of the lens.

As shown in FIG. 15, when power is applied to the first coil member 1250, the first electromagnetic field generated by the first coil member 1250 interacts with the magnetic field generated by the magnet 1500. The first blade 1200 is raised.

In this case, the first yoke 1900 induces the magnetic force line generated at the N pole, which is the lower end of the magnet 1500, to return to the S pole through the first coil member 1250.

As the first blade 1200 ascends, the first elastic member 1700 mounted on the upper side of the first blade 1200 is relaxed in an upward direction with an inner side ascending with the first blade 1200. .

In addition, the first elastic member 1700 is also connected to the inside of the first elastic member 1700 and the second blade 1300 connected to the inside of the first blade 1200 by the second elastic member 1800. The inner side of) rises and rises together.

In this case, as shown in FIG. 8, since the second blade 1300 on which the second coil member 1350 is mounted moves only in the vertical direction without moving left and right, the second coil member 1350 and the magnet 1500. The spacing between the inner surfaces of h) does not change.

Therefore, when the second blade 1300 moves horizontally, the magnetic field of the magnet 1500 is uniformly conducted to all of the second coil members 1350 disposed on both sides of the second blade 1300, and thus the second blade 1300. The horizontal movement of the 1300 is smoothly made.

In addition, the first coil member 1250 may move downward when the direction of the applied power is reversed.

Meanwhile, when power is applied to the second coil member 1350 while the first blade 1200 is raised, as shown in FIG. 16, the second blade 1300 is formed inside the first blade 1200. It horizontally moves to the left independently of the first blade 1200.

As the second blade 1300 moves to the left side, the second elastic member 1800 is deformed to the left side, and the second elastic member 1800 moves the second blade 1300 to the right side by elastic restoring force. Elastic support.

The second blade 1300 may be moved in the right or front and rear directions according to the direction of the current applied to the second coil member 1350.

As such, the magnet 1500 is disposed between the inner surface of the first blade 1200 and the outer surface of the second blade 1300, and the first blade 1200 and the second blade 1300 are disposed. The second blade 1300 is horizontally moved independently of the first blade 1200 so that the first blade 1200 is mounted at the same time as the second blade 1300. The interval between the two coil members 1350 and the magnet 1500 is kept constant, so that the magnetic field of the magnet 1500 is mounted on the second coil members 1350 respectively mounted on both sides of the second blade 1300. All are uniformly conducted so that the horizontal movement of the second blade 1300 is smoothly performed.

On the contrary, when the horizontal movement of the second blade 1300 moves horizontally between the first coil member 1250 and the magnet 1500, all the gaps are uniformly maintained so that the first blade 1200 can be smoothly moved. do.

The small camera device of the present invention is not limited to the above-described embodiment, but can be modified and implemented in various ways within the scope of the technical idea of the present invention.

1 is a perspective view showing a conventional compact camera device,

2 is an exploded perspective view showing a conventional compact camera device,

3 is an exploded perspective view illustrating an enlarged view of portion A of FIG. 2;

4 is a perspective view showing a compact camera device according to a first embodiment of the present invention,

5 is an exploded perspective view showing a small camera device according to a first embodiment of the present invention,

FIG. 6 is a partially exploded perspective view illustrating an enlarged view of FIG. 5D;

7 to 9 is an operating state view as seen from B-B of FIG.

10 is an operating state diagram of a power supply terminal according to the present invention as seen from C-C of FIG.

11 is a perspective view of a compact camera device according to a second embodiment of the present invention,

12 is a one-directional exploded perspective view of a compact camera device according to a second embodiment of the present invention;

13 is an exploded perspective view from another direction of the compact camera device according to the second embodiment of the present invention.

FIG. 14 is a cross-sectional view of the compact camera apparatus according to the second embodiment of the present invention as seen from E-E of FIG.

15 and 16 are operational state diagrams of the compact camera apparatus according to the second embodiment of the present invention as seen from E-E of FIG.

<Description of the symbols for the main parts of the drawings>

400,1200: first blade, 410,1250: first coil member,

300,1300: second blade, 310,1350: second coil member,

500,1500: magnet, 600,1600: second yoke,

420, 1700: first elastic member, 420, 1800: second elastic member,

900,1900: First York,

Claims (6)

A housing; A first blade which is moved up and down inside the housing and has a first coil member mounted on an outside thereof; A second blade horizontally moved inside the housing and having a second coil member mounted on an outside thereof; A magnet comprising a first magnet disposed outside the second coil member and a second magnet disposed below the first magnet outside the second coil member; A first yoke mounted on an upper portion of the first magnet or a lower portion of the second magnet; , &Lt; / RTI &gt; The first blade is moved by the interaction between the first electromagnetic field generated when the power is applied to the first coil member and the magnetic field generated by the magnet, The second blade is horizontally moved by the interaction between the second electromagnetic field generated when the power is applied to the second coil member and the magnetic field generated by the magnet, The first yoke is a compact camera device, characterized in that to guide the magnetic force lines generated at the north pole of the magnet to the S pole through the first coil member or the second coil member. The method of claim 1, And the first yoke protrudes in the direction of the first coil member. The method of claim 2, The second blade is mounted to be horizontally moved inside the first blade, The magnet is disposed between the inner surface of the first blade and the outer surface of the second blade is fixed to the housing, The first coil member is wound around the first blade, And the second coil member is wound on the side surface of the second blade in a direction orthogonal to the winding direction of the first coil member. The method of claim 2, The first blade is mounted to be moved up and down inside the second blade, The magnet is fixedly mounted to the housing on the outside of the second blade, The first coil member is wound around the first blade, And the second coil member is wound on the side surface of the second blade in a direction orthogonal to the winding direction of the first coil member. The method according to claim 3 or 4, A second yoke mounted between the first magnet and the second magnet and inserted into a central portion of the second coil member; It is made, including more The first magnet and the second magnet is a compact camera device, characterized in that the polarity is arranged up and down symmetrical around the second yoke. The method of claim 5, The second coil member is a compact camera device, characterized in that the vertical length is less than the sum of the vertical length of the magnet and the second yoke.

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