KR20120027751A - Compact camera device - Google Patents

Abstract

According to an embodiment of the present invention, eight elastic members which respectively supply power to the first coil member and the second coil member while supporting the first blade are spaced apart from each other along a circumference of the housing, thereby allowing the elastic member to move horizontally. It is to provide a compact camera device that can be moved in the correct direction to reduce the load added to the first blade by making the deformation direction of the constant.
The compact camera device of the present invention comprises: a housing which is opened up and down; A first blade which is vertically open and mounted to be moved to the left and right in the housing by the magnet and the first coil member; A second blade installed inside the lens and mounted to be moved upward and downward in the first blade by the magnet and the second coil member; A power connection member mounted on an upper portion of the housing and connected to an external power source; The upper end is mounted on the upper portion of the housing, the lower end is mounted to the lower portion of the first blade comprises a wire-shaped elastic member for elastically supporting the first blade in the left and right directions, the elastic member is, A first spaced apart from each other along the circumference of the second blade, an upper end electrically connected to the power connection member, and a lower end electrically connected to the first coil member to supply power to the first coil member. Wire springs; Four pieces are arranged to be spaced apart from the first wire spring along the circumference of the second blade, the upper end is electrically connected to the power connection member, and the lower end is electrically connected to the second coil member. A second wire spring for supplying power to the coil member; It is made, including.

Description

Compact camera device {

The present invention relates to a small camera device, and more particularly, to a small camera device that simultaneously performs focus adjustment and image stabilization of a subject by moving a lens in a vertical direction and a horizontal direction by using a coil and a magnet.

1 is an exploded perspective view of a conventional small camera device, Figure 2 is an exploded perspective view showing an enlarged portion A of FIG.

1 and 2 is a diagram of the invention filed by the applicant of the applicant No. 10-2008-0128375.

As shown in FIGS. 1 and 2, a conventional small camera apparatus includes a cover 20, a second blade 30 mounted to be moved horizontally on the cover 20, and the second blade 30. A first blade 40 mounted upwardly and downwardly and including a lens (not shown) therein; a first coil member 41 mounted outside the first blade 40; and the second blade; The second coil member 31 mounted on the outside of the blade 30, the magnet 50 mounted on the side of the cover 20, one end is in contact with the magnet 50, the other end is the first coil member And a yoke member 60 disposed adjacent to 41.

The first blade 40 is elastically supported in the vertical direction by the first elastic member 42 having an outer side mounted on the second blade 30 and an inner side mounted on the first blade 40.

In addition, the first blade 40 may be formed by the magnet 50 to induce interaction between the magnetic field induced through the yoke member 60 and the electromagnetic field generated when power is applied to the first coil member 41. By moving up and down with the lens to adjust the focus of the subject.

The second blade 30 is elastically supported in the horizontal direction by a second elastic member 32 having one end mounted on the cover 20 and the other end mounted on the second blade 30.

In addition, the second blade 30 is horizontal due to the interaction between the magnetic field generated by the magnet 50 and induced through the yoke member 60 and the electromagnetic field generated when power is applied to the second coil member 31. Move to compensate for camera shake.

As such, in order to move the first blade 40 and the second blade 30, power must be applied to the first coil member 41 and the second coil member 31, respectively.

To this end, the second coil member 31 is connected to the second elastic member 32 to receive power, and the first coil member 41 is connected to the first elastic member 42 to supply power. Receive.

That is, the second elastic member 32 has an upper end connected to an external power source to supply power to the second coil member 31, and the first elastic member 42 is on the outside of the cover 20. Extension portion 43 extending in the direction is formed, the extension portion 43 is connected to an external power supply to supply power to the first coil member 41.

However, since the first extension part 43 is formed in the horizontal direction and the second elastic member 32 is formed in the vertical direction, the first extension part 43 when the second blade 30 moves horizontally. ) And the second elastic member 32 are elastically deformed in different directions, which causes a problem that the load added to the second blade 30 is increased.

In addition, when the second blade 30 moves horizontally, the first elastic member 42 and the second elastic member 32 are deformed in different directions so that the second blade 30 cannot move in the correct direction. There is.

The present invention is to solve the above problems, by arranging eight elastic members for supplying power to each of the first coil member and the second coil member while supporting the first blade up and down spaced apart along the circumference of the housing, An object of the present invention is to provide a compact camera device capable of reducing the load added to the first blade and moving in the correct direction by making the deformation direction of the elastic member constant during horizontal movement of the first blade.

In order to achieve the above object, the compact camera device of the present invention, the upper and lower housings; A first blade which is vertically open and mounted to be moved to the left and right in the housing by the magnet and the first coil member; A second blade installed inside the lens and mounted to be moved upward and downward in the first blade by the magnet and the second coil member; A power connection member mounted on an upper portion of the housing and connected to an external power source; The upper end is mounted on the upper portion of the housing, the lower end is mounted to the lower portion of the first blade comprises a wire-shaped elastic member for elastically supporting the first blade in the left and right directions, the elastic member is, A first spaced apart from each other along the circumference of the second blade, an upper end electrically connected to the power connection member, and a lower end electrically connected to the first coil member to supply power to the first coil member. Wire springs; Four pieces are arranged to be spaced apart from the first wire spring along the circumference of the second blade, the upper end is electrically connected to the power connection member, and the lower end is electrically connected to the second coil member. A second wire spring for supplying power to the coil member; It is made, including.

A connection substrate mounted on a lower portion of the first blade and having a copper foil portion connected to a lower end of the first wire spring and the second wire spring; It further comprises, wherein the copper foil portion is composed of four, and are spaced apart from each other along the circumference of the connecting substrate, the first through-hole electrically connected to the first coil member; A second through hole formed of two and spaced apart from the first through hole along a circumference of the connection board and electrically connected to the second coil member; A third through hole formed of two and spaced apart from the first through hole and the second through hole along a circumference of the connection substrate; And a first wire spring having an upper end electrically connected to the power connection member, and a lower end electrically connected to the first through hole to supply power to the first coil member. At least two of the wire springs are electrically connected to the power connection member at an upper end thereof, and electrically connected to the second through hole at a lower end thereof to supply power to the second coil member. The dog has an upper end connected to an upper portion of the housing, and a lower end connected to the third through hole.

A yoke member having four and one mounted to each side of the housing, one end of which is in contact with the magnet and the other end of which is disposed adjacent to the second coil member; It further comprises, but the magnet is made of eight, formed in pairs of two each arranged at the top and bottom of one end of the yoke member is inserted into the side of the housing, the first coil member is hollow It is wound in a shape, and consists of four, respectively mounted on the outside of the first blade to face the magnet, the second coil member is made of one is wound along the outer peripheral surface of the second blade, the yoke member is the other end It penetrates the side of the first blade and the first coil member to protrude in the direction of the second coil member to induce magnetic force lines generated in the magnet to circulate through the second coil member.

The first coil member is composed of four mounted on the outer side of the first blade to face the magnet, the second coil member is made of one is wound along the outer peripheral surface of the second blade, the first coil member The two coils arranged in opposite directions are interconnected to each other so that the (+) and (-) poles are electrically connected to the first through-holes respectively different from each other, and the second coil member is connected to the (+) pole and The poles are electrically connected to the second through holes that are different from each other.

A leaf spring disposed below the connection board, the outer side of which is mounted to the first blade, and the inner side of which is mounted to the second blade to elastically support the second blade in the vertical direction; It further comprises, wherein the outer side of the leaf spring is electrically connected to the second through hole, the inner side of the leaf spring is electrically connected to the second coil member to supply power to the second coil member. .

A guide groove is formed in the outer circumferential surface of the second blade in the leaf spring direction, and a locking groove communicating with the guide groove is formed in the leaf spring, and an end of the second coil member is formed along the guide groove. It is inserted into the locking groove and connected to the leaf spring.

The first wire spring and the second wire spring are disposed in the up and down direction between the first blade and the second blade, the linear distance between the first wire spring disposed in the diagonal direction is spaced in the diagonal direction It is equal to the straight line distance between the second wire springs.

Four planar portions having a planar shape are formed to be spaced apart from each other on the outer side of the second blade, and four chamfered portions having a planar shape are formed to be integrally connected with the planar portion between the planar portions, and the second coil member Is wound along the flat portion and the chamfering portion, and the other end of the yoke member is formed in a plane shape parallel to the flat portion and is disposed to face the second coil member wound on the flat portion, and is spaced apart from each other. An extension line between the first wire spring and the second wire spring is parallel to the chamfered portion.

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

Four first wire springs and two second wire springs are disposed to be spaced apart from each other along the circumference of the second blade, so that the first wire spring and the second wire spring are deformed in a horizontal movement of the first blade. It is effective to reduce the load added to the first blade by the constant and to move the first blade in the correct direction.

In addition, the first wire spring is connected to the first coil member, and the second wire spring is connected to the second coil member, thereby eliminating the need to connect separate wires to the first coil member and the second coil member. The current can be supplied through the first wire spring and the second wire spring, thereby simplifying the structure and preventing an imbalance in the first blade due to a separate wire.

The first wire spring is electrically connected to the first through hole, any two of the second wire springs are electrically connected to the second through hole, and the other two of the second wire springs are connected to the first through hole. The first coil member and the second wire spring are fixed to the first through hole, the second through hole and the third through hole by being connected to the third through hole. A second coil member can be connected to the first through hole and the second through hole, thereby facilitating assembly.

The inner side of the leaf spring is electrically connected to the second coil member, thereby simplifying the structure by electrically connecting the second through-hole and the second coil member through the leaf spring without using a separate wire, Since the length of the end of the second coil member can be minimized, the durability of the second coil member can be minimized, and a separate wire can be prevented from causing an imbalance during vertical driving of the second blade.

The outer peripheral surface of the second blade is formed in the guide groove in communication with the engaging groove is inserted into the end of the second coil member is inserted, thereby preventing the end of the second coil member from being damaged by external friction to improve durability It is effective to let.

The linear distance between the first wire springs spaced in the diagonal direction is the same as the linear distance between the second wire springs spaced in the diagonal direction, thereby minimizing the diagonal distance between the first wire springs and the second wire springs. This has the effect of reducing the overall size of the device.

The second blade is formed with a planar portion having a planar shape in which the second coil member is wound, such that the second coil member is disposed to face the other end of the yoke member to be spaced apart from the second coil member and the other end of the yoke member. Minimizing the distance, thereby increasing the range of the magnetic reaction between the second coil member and the yoke member has the effect of improving the driving force of the second coil member.

1 is an exploded perspective view of a conventional compact camera device,
FIG. 2 is an exploded perspective view illustrating an enlarged portion A of FIG. 1;
3 is a perspective view of a compact camera device according to an embodiment of the present invention,
4 is a partially exploded perspective view of a compact camera device according to an embodiment of the present invention;
5 is an exploded perspective view enlarging B of FIG. 4;
6 is a cross-sectional view seen from CC of FIG.
7 is a cross-sectional view taken from the DD of FIG. 2;
8 is a cross-sectional view taken from the EE of FIG. 2;
9 is a plan view of a connecting substrate and a leaf spring according to an embodiment of the present invention;
10 and 11 is a flowchart of the operation of the compact camera device according to an embodiment of the present invention,

3 is a perspective view of a small camera device according to an embodiment of the present invention, Figure 4 is a partially exploded perspective view of a small camera device according to an embodiment of the present invention, Figure 5 is a small camera device according to an embodiment of the present invention Main part exploded perspective view, Figure 6 is a sectional view seen from BB of Figure 2, Figure 7 is a sectional view seen from CC of Figure 2, Figure 8 is a sectional view seen from DD of Figure 2, Figure 9 is a connecting substrate according to an embodiment of the present invention And a top view of the leaf spring.

3 to 9, the compact camera device according to the embodiment of the present invention includes a housing 100, a first blade 200, a second blade 300, a magnet 410, and a yoke member 420. , The first coil member 430, the second coil member 440, the power connection member 450, the elastic member 500, the connection substrate 600, and the leaf spring 700.

The housing 100 is formed to open up and down in a hexahedral shape, as shown in Figure 4 consists of an upper plate 110 and a lower plate 120.

The upper plate 110 has a rectangular shape in the center of the first opening 111 is formed in a circular shape, the vertex portion of the 'b' shaped first supporting protrusion 112 is formed to protrude downward.

In addition, the upper plate 110 is formed with a first insertion hole 113 in which the upper end of the elastic member 500 is inserted, as will be described later.

The first insertion hole 113 is composed of eight and formed in two adjacent to the vertex portion of the upper plate (110).

The lower plate 120 has a quadrangular shape and is disposed below the upper plate 110, and a second opening 121 is formed at a central portion thereof to communicate with the first opening 111. The second support protrusions 122 are formed to protrude in the upward direction, respectively.

The upper plate 110 and the lower plate 120 are assembled such that an upper surface of the second support protrusion 122 is in contact with a lower surface of the first support protrusion 112, and an empty space is formed therein.

A cover 150 made of a plate is mounted on the outside of the housing 100 to surround the upper and side portions of the housing 100.

The first blade 200 is vertically open in a hexahedral shape, and is mounted to be moved in the left and right directions in the housing 100 by the magnet 410 and the first coil member 430.

In addition, a through hole 210 into which the other end of the yoke member 420 is inserted is formed at a side portion of the first blade 200.

The through-holes 210 are formed in four in a rectangular shape, one on each side, and penetrate the outside and the inside of the first blade 200.

In addition, a second insertion hole 220 in which a lower end of the elastic member 500 is inserted is formed at a vertex portion of the first blade 200.

As illustrated in FIG. 6, eight second insertion holes 220 are formed, and two second insertion holes 220 are formed at portions adjacent to the vertex portion of the first blade 200.

The second insertion hole 220 is disposed on the same vertical line as the first insertion hole 113, respectively.

The first coil member 430 is mounted to the outside of the first blade 200 as described later.

The second blade 300 is formed in an octagonal shape, and is vertically opened so that a lens (not shown) is installed therein.

The planar portion 310 and the chamfer 320 are formed on the outer side of the second blade 300, respectively, as shown in FIG. 6.

The planar portion 310 is formed in a planar shape and is formed of four and spaced apart in all directions along the outer side of the second blade 300.

The chamfer 320 is made of four in a planar shape, is formed inclined between the planar portion 310 is integrally connected to the planar portion 310.

In addition, the width of the chamfer 320 is smaller than the width of the flat portion 310.

The second coil member 440 is wound around the flat portion 310 and the chamfer 320 as described later.

As described above, the planar portion 310 having a planar shape in which the second coil member 440 is wound is formed on the second blade 300, so that the second coil member 440 may have the yoke member ( It is disposed to face the other end of the 420 to minimize the separation distance between the second coil member 440 and the other end of the yoke member 420, thereby the second coil member 440 and the yoke member 420 There is an effect of increasing the range of the magnetic reaction occurs between the second coil member 440 to improve the driving force.

In addition, the guide groove 330 is formed in the outer circumferential surface of the second blade 300 in the direction of the leaf spring 700, that is, downward.

Two guide grooves 330 are formed to be symmetrically formed in two, and communicate with the locking grooves 711 of the leaf spring 700 as described below.

The guide groove 330 guides the end of the second coil member 440 toward the leaf spring 700 as described below.

As described above, a guide groove 330 is formed on the outer circumferential surface of the second blade 300 so as to communicate with the locking groove 711 so that the end of the second coil member 440 is inserted into the second blade member 300. The end of 440 is prevented from being damaged by external friction, thereby improving durability.

The second blade 300 is mounted to be moved up and down inside the first blade 200 by the magnet 410 and the second coil member 440, as will be described later.

In addition, a top spring 350 made of a rectangular plate is mounted on the second blade 300.

The top spring 350 has an outer side mounted on the upper portion of the first blade 200 and an inner side mounted on the upper portion of the second blade 300 so that the top spring 350 together with the leaf spring 700 may be formed. The two blades 300 are elastically supported in the vertical direction from the first blade 200.

The magnet 410 is formed in a rectangular shape, the polarity is separated in the vertical direction, and consists of eight.

The magnet 410 is a pair of two are inserted into the side of the housing 100, and are spaced apart up and down,

The magnets 410 are arranged such that the same poles face each other in the vertical direction.

The yoke member 420 is mounted between the magnets 410.

The yoke member 420 is a magnetic material and is formed in a quadrangular shape, and consists of four yoke members 420, one mounted at each side of the housing 100.

One end of the yoke member 420 is disposed between the pair of magnets 410 to be in contact with the magnet 410, and the other end thereof is disposed to be adjacent to the second coil member 440.

That is, the other end of the yoke member 420 penetrates through the center of the first coil member 430 and is inserted into the through hole 210 of the first blade 200 as shown in FIGS. 5 and 7. It is disposed close to the second coil member 440.

The yoke member 420 induces a magnetic force line generated in the magnet 410 to circulate from the N pole of the magnet 410 to the S pole of the magnet 410 through the second coil member 440. do.

In addition, the other end of the yoke member 420 is formed in a plane shape parallel to the plane portion 310 of the second blade 300, and the second coil member 440 wound on the plane portion 310 Faced.

That is, the other ends of the yoke member 420 are spaced apart from each other in parallel with the second coil member 440 wound on the flat portion 310.

On the other hand, the first coil member 430 is wound in a hollow oval shape, consisting of four mounted on the outside of the first blade 200, the central portion is in communication with the through hole 210.

In addition, the first coil member 430 is disposed to face the pair of magnets 410, respectively.

In addition, the first coil member 430 is connected to each other disposed in a direction facing each other, although not shown in the figure is formed an end of the (+) pole and (-) pole protruding.

As described below, the first coil member 430 is electrically connected to the first through hole 611 of the connecting substrate 600 with a positive pole end and a negative pole end.

The second coil member 440 is made of one, it is wound along the outer peripheral surface of the second blade (300).

That is, the second coil member 440 is wound along the plane portion 310 and the chamfer 320 of the second blade 300.

In addition, ends of the second coil member 440 are formed to protrude from the positive electrode and the negative electrode.

As described later, the second coil member 440 is electrically connected to the second through hole 612 of the connecting substrate 600, respectively, with a positive pole end and a negative pole end.

On the other hand, the power connection member 450 is made of a flexible printed circuit board (FPCB), is formed in a rectangular shape is mounted on the upper portion of the housing 100.

The power connection member 450 is connected to an external power source and supplies power to the first coil member 430 and the second coil member 440 through the elastic member 500.

The elastic member 500 is made of a conductor, is formed in a wire shape, the upper end is mounted on the upper portion of the housing 100, the lower end is mounted on the lower portion of the first blade 200 is the first blade ( 200 is elastically supported in the left and right directions.

More specifically, the elastic member 500 is composed of a first wire spring 510 and a second wire spring 520.

The first wire spring 510 is formed of four, and each of the first wire spring 510 is made of a wire material of a conductor material and is spaced apart from each other along the circumference of the second blade 300.

That is, the first wire spring 510 is disposed between the chamfer 320 of the first blade 200 and the second blade 300, as shown in Figure 6, the first blade 200 Each one is disposed adjacent to the vertex portion of.

As shown in FIG. 8, an upper end of the first wire spring 510 is inserted into and fixed to the first insertion hole 113, and is electrically connected to the power connection member 450.

That is, an upper end of the first wire spring 510 is soldered to the power connection member 450 and electrically connected to the power connection member 450.

In addition, a lower end of the first wire spring 510 is inserted and fixed to the second insertion hole 220, and is electrically connected to the first coil member 430 by the connection substrate 600 as described below. Power is supplied to the first coil member 430.

The second wire springs 520 are formed of four, and each of the second wire springs 520 is formed of a wire material of a conductor material and is spaced apart from each other along the circumference of the second blade 300.

That is, the second wire spring 520 is disposed between the chamfer 320 of the first blade 200 and the second blade 300, as shown in Figure 6, the first blade 200 Each one is disposed adjacent to the vertex portion of.

As illustrated in FIG. 8, upper ends of the second wire springs 520 are inserted into and fixed to the first insertion holes 113, and any two of the upper ends of the second wire springs 520 are the power source. It is electrically connected to the connection member 450.

A lower end of the second wire spring 520 is inserted and fixed to the second insertion hole 220, and the two second wire springs 520 electrically connected to the power connection member 450 are described below. A lower end is electrically connected to the second coil member 440 by the connecting substrate 600 and the leaf spring 700 to supply power to the second coil member 440.

The other two of the second wire springs 520 are not electrically connected to the power connection member 450 and the second coil member 440.

In some cases, the second wire spring 520 that is not electrically connected to the power connection member 450 and the second coil member 400 may be removed. In this case, the first blade 200 may be removed. When the horizontal movement of the second wire spring 520 is different from the magnitude of the force acting in the place where the mounting and not mounted, the first blade 200 is tilted or moved in the wrong direction.

Therefore, as in the embodiment of the present invention, the second wire spring 520 is preferably made of four like the first wire spring 510 to elastically support the first blade 200.

In addition, the second wire spring 520 is spaced apart from the first wire spring 510, and an extension line between the second wire spring 520 and the first wire spring 510 spaced apart from each other is adjacent to the surface. It is parallel to the mounting (320).

The straight line distance between the first wire springs 510 spaced in the diagonal direction is the same as the straight line distance between the second wire springs 520 spaced in the diagonal direction.

That is, the first wire spring 510 and the second wire spring 520 are symmetrically disposed in the diagonal direction of the second blade 300, respectively, and the chamfer 320 in the first wire spring 510. ) Is the same as the straight line distance from the second wire spring 520 to the chamfer 320.

As such, the straight line distance between the first wire springs 510 spaced in the diagonal direction is the same as the straight line distance between the second wire springs 520 spaced in the diagonal direction, thereby the first wire spring 510 and the Minimizing the diagonal distance of the second wire spring 520 has the effect of reducing the overall size of the device.

On the other hand, the connection substrate 600 is fixed to the lower portion of the first blade 200, the copper foil portion 610 is connected to the lower end of the first wire spring 510 and the second wire spring 520, respectively Is formed.

Specifically, the copper foil part 610 includes a first through hole 611, a second through hole 612, and a third through hole 613 as illustrated in FIGS. 5 and 9.

The first through hole 611 is vertically open in a cylindrical shape, and a conductive material is plated on an inner circumferential surface thereof.

In addition, the first through-hole 611 is composed of four are spaced apart from each other along the circumference of the connecting substrate 600, each is disposed on the same vertical line with the second insertion hole 220.

In addition, an end of the first coil member 430 is soldered to the first through hole 611 to be electrically connected to the first coil member 430.

That is, the (+) pole end and the (−) pole end of the first coil member 430 are electrically connected to the first through holes 611 which are different from each other.

The first through hole 611 is electrically connected to a lower end of the first wire spring 510 to supply power to the first coil member 430.

That is, the lower end of the first wire spring 510 is soldered to the first through hole 611 to supply power to the first coil member 430.

The second through hole 612 is opened up and down in a cylindrical shape similar to the first through hole 611, and a conductive material is plated on an inner circumferential surface thereof.

The second through hole 612 may be formed to be spaced apart from the first through hole 611 along the circumference of the connecting substrate 600, and may be disposed on the same vertical line as the second insertion hole 220. Is placed.

In addition, the second through hole 612 is electrically connected to the second coil member 440 by the elastic member 500 as described below.

That is, the (+) pole end and the (−) pole end of the second coil member 440 are electrically connected to the second through holes 612 which are different from each other through the elastic member 500 as described below. .

Any two of the second wire springs 520 electrically connected to the power connection member 450 are soldered and electrically connected to the second through hole 612.

The third through hole 613 is opened up and down in a cylindrical shape similar to the first through hole 611, and a conductive material is plated on the inner circumferential surface.

The third through hole 613 is formed in two, and is spaced apart from the first through hole 611 and the second through hole 612 along the circumference of the connection substrate 600.

In addition, the third through holes 613 are disposed on the same vertical line as the second insertion holes 220, respectively.

The other two of the second wire springs 520 are inserted into and fixed to the third through hole 613.

As such, the first wire spring 510 is electrically connected to the first through hole 611, and any two of the second wire springs 520 are electrically connected to the second through hole 612. The other two of the second wire springs 520 are connected to the third through hole 613, so that the first wire springs 510 and the second wire springs 520 are assembled to the first wire springs 520. The first coil member 430 and the second coil member 440 are first penetrated in a state of being fixed to the through hole 611, the second through hole 612, and the third through hole 613. It can be connected to the hole 611 and the second through hole 612 has an effect of facilitating assembly.

The leaf spring 700 elastically supports the second blade 300 in the vertical direction from the first blade 200.

In detail, the leaf spring 700 includes a positive spring 710 and a negative spring 720.

The anode spring 710 is formed of a thin plate, and is disposed below the connection substrate 600.

The anode spring 710 has an outer side mounted to the first blade 200 and an inner side mounted to the second blade 300.

That is, as shown in FIG. 5, the outer side of the anode spring 710 has a triangular shape, and is fixedly mounted to the first blade 200 by interviewing a lower surface of a vertex portion of the first blade 200. The inner side is formed in a half arc shape and is fixed to the second blade 300 in contact with the bottom surface of the second blade 300.

The outer and inner sides of the positive spring 710 are connected to each other to be elastically deformed.

In addition, the connection portion 730 is formed to protrude along the side of the connection substrate 600 on the outside of the anode spring 710.

The connection part 730 is electrically connected to the second through hole 612.

A locking groove 711 is formed in the anode spring 710 to communicate with the guide groove 330.

The locking groove 711 is formed in a rectangular shape, the outer width is formed narrower than the inner width.

The (+) pole end and the (−) pole end of the second coil member 440 disposed along the guide groove 330 are respectively inserted into the locking groove 711 to be soldered and fixed.

In some cases, the first wire spring 510, the second wire spring 520, the first coil member 430, and the second coil member 440 may be solder cream or conductive adhesive other than soldering. As a result, the power connection member 450, the connection substrate 600, and the leaf spring 700 may be electrically connected to each other.

The cathode spring 720 is the same as the cathode spring 710 except that the cathode spring 710 is symmetrically disposed with respect to the anode spring 710 based on the second blade 300, and thus, detailed description thereof will be omitted.

In this way, the inner side of the leaf spring 700 is electrically connected to the second coil member 440, so that the second through-hole 612 and the through the leaf spring 700 without using a separate wire The second coil member 440 may be electrically connected to simplify the structure, and the length of the end of the second coil member 440 may be minimized, thereby improving durability. It is possible to prevent the imbalance caused when the two blades 300 are driven up and down.

In addition, the engaging groove 711 is formed in communication with the guide groove 330 in the leaf spring 700, the end of the second coil member 440 can be easily fixed to the leaf spring 700 There is an effect of improving the assembly.

It describes the operation of the small camera module according to an embodiment of the present invention made of the above configuration.

7 and 8 show the initial state of the first blade 200 and the second blade 300, Figure 10 shows the up and down operating state of the second blade 300, Figure 11 is the The left and right operating states of the first blade 200 are shown.

As shown in FIGS. 7 and 8, the plate spring 700 and the top spring 350 are horizontally horizontal to each other before power is applied to the first coil member 430 and the second coil member 440. The elastic member 500 is disposed vertically in the vertical direction.

And the other end of the yoke member 420 is disposed in the center of the second coil member 440, the left and right intervals of the magnet 410 and the first coil member 430 are equally spaced.

As shown in FIG. 10, power is supplied to the second coil member 440 through the power connection member 450, the second wire spring 520, the connection substrate 600, and the leaf spring 700. When supplied, the second blade 300 is moved upward by the interaction between the electromagnetic field generated by the second coil member 440 and the magnetic force line of the magnet 410 induced through the yoke member 420. .

As the second blade 300 ascends, the top spring 350 and the leaf spring 700 are elastically deformed in an upward direction, respectively, and elastically support the second blade 300 downward by an elastic restoring force. do.

In this case, the first wire spring 510, the second wire spring 520, and the first blade 200 do not move.

After the power supply to the second coil member 440 is stopped, the second blade 300 is moved downward by the elastic restoring force of the top spring 350 and the leaf spring 700.

Of course, even when the direction of current is reversely supplied to the second coil member 440, the second blade 300 is moved downward.

As such, the second blade 300 adjusts the focus of the image captured by the image sensor by adjusting a distance between the lens installed therein and the image sensor disposed below the housing 100 while moving up and down.

Meanwhile, as shown in FIG. 11, when power is supplied to the first coil member 430 through the power connection member 450, the first wire spring 510, and the connection substrate 600, the first coil. The first blade 200 is moved in the right direction by the interaction between the electromagnetic field generated by the member 430 and the magnetic force line generated by the magnet 410.

When the first blade 200 moves to the right, the first wire spring 510 and the second wire spring 520 are elastically deformed while the lower end moves to the right, and the first blade 200 is elastically restored. Is elastically supported in the left direction.

In addition, when the first blade 200 moves to the right side, the second blade 300, the leaf spring 700, the top spring 350, and the connecting substrate disposed inside the first blade 200. Also move 600 to the right.

Thereafter, when the power supply to the first coil member 430 is stopped, the first blade 200 moves to the left side by the elastic restoring force of the first wire spring 510 and the second wire spring 520. It is restored to the initial position.

Of course, even when the direction of the current is reversely supplied to the first coil member 430, the first blade 200 is moved to the left.

Through this process, the first blade 200 corrects the shaking of the image captured by the image sensor by hand movement by moving the lens installed in the second blade 300 in the horizontal direction.

As described above, the first wire spring 510 and the second wire spring 520 are formed of four, respectively, and are spaced apart from each other along the circumference of the second blade 300, so that the first blade 200 is moved horizontally. The deformation direction of the first wire spring 510 and the second wire spring 520 is constant so as to reduce the load applied to the first blade 200 and to move the first blade 200 in the correct direction. It is effective.

That is, the first wire spring 510 and the second wire spring 520 are each made of a long wire rod in the vertical direction and are arranged in parallel to each other, and are arranged symmetrically in a diagonal direction, so that the first blade spring of the first blade spring During the horizontal movement, the first blade 200 can correctly move in the direction of movement induced by the interaction of the first coil member 430 and the magnet 410.

In addition, the first wire spring 510 is connected to the first coil member 430, and the second wire spring 520 is connected to the second coil member 440, thereby providing the first coil member 430. ) And the second coil member 440 to supply current through the first wire spring 510 and the second wire spring 520 without the need to connect a separate wire, simplifying the structure, and a separate wire As a result, an imbalance may be prevented from occurring in the first blade 200.

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

100: housing, 110: upper plate, 113: first insertion hole, 120: lower plate, 200: first blade, 210: through hole, 220: second insertion hole, 300: second blade, 310: flat portion, 320: Chamfering, 330: guide groove, 350: top spring, 410: magnet. 420: yoke member, 430: first coil member, 440: first coil member, 450: power connection member, 500: elastic member, 510: first wire spring, 520: second wire spring, 600: connecting substrate, 610 : Copper foil part, 611: 1st through hole, 612: 2nd through hole, 613: 3rd through hole, 700: Leaf spring, 710: Anode spring, 711: Hanging groove, 720: Cathode spring, 730: Connection part,

Claims (8)

Upper and lower housings;
A first blade which is vertically open and mounted to be moved to the left and right in the housing by the magnet and the first coil member;
A second blade installed inside the lens and mounted to be moved upward and downward in the first blade by the magnet and the second coil member;
A power connection member mounted on an upper portion of the housing and connected to an external power source;
The upper end is mounted to the upper portion of the housing, the lower end is mounted to the lower portion of the first blade made of a wire-shaped elastic member for elastically supporting the first blade in the left and right directions,
The elastic member
It is composed of four spaced apart from each other along the circumference of the second blade, the upper end is electrically connected to the power connection member, the lower end is electrically connected to the first coil member to supply power to the first coil member A first wire spring;
Four pieces are arranged to be spaced apart from the first wire spring along the circumference of the second blade, the upper end is electrically connected to the power connection member, and the lower end is electrically connected to the second coil member. A second wire spring for supplying power to the coil member; Small camera device, characterized in that consisting of. The method of claim 1,
A connection substrate mounted on a lower portion of the first blade and having a copper foil portion connected to a lower end of the first wire spring and the second wire spring; Including more,
The copper foil portion,
A first through hole consisting of four parts spaced apart from each other along the circumference of the connection board and electrically connected to the first coil member;
A second through hole formed of two and spaced apart from the first through hole along a circumference of the connection board and electrically connected to the second coil member;
A third through hole formed of two and spaced apart from the first through hole and the second through hole along a circumference of the connection substrate; , ≪ / RTI >
The first wire spring has an upper end electrically connected to the power connection member, and a lower end is electrically connected to the first through hole to supply power to the first coil member.
Any two of the second wire springs have an upper end electrically connected to the power connection member, and a lower end electrically connected to the second through hole to supply power to the second coil member.
The other two of the second wire spring is a small camera device, characterized in that the upper end is connected to the upper portion of the housing, the lower end is connected to the third through hole. The method according to claim 1 or 2,
A yoke member having four and one mounted to each side of the housing, one end of which is in contact with the magnet and the other end of which is disposed adjacent to the second coil member; It is made, including more
The magnet is composed of eight, two pairs of two are respectively disposed on the upper and lower ends of the end of the yoke member is inserted into the side of the housing,
The first coil member is wound in a hollow shape, and consists of four, respectively mounted on the outside of the first blade to face the magnet,
The second coil member is made of one is wound along the outer peripheral surface of the second blade,
The yoke member is formed so that the other end is protruded toward the second coil member through the side of the first blade and the first coil member, the magnetic force lines generated in the magnet is circulated through the second coil member Small camera device, characterized in that. The method of claim 2,
The first coil member is composed of four mounted on the outside of the first blade to face the magnet, respectively
The second coil member is made of one is wound along the outer peripheral surface of the second blade,
The first coil member is connected to the two mutually arranged in a direction facing each other and is electrically connected to the first through-hole each of which the (+) and (-) poles are different from each other,
The second coil member is a compact camera device, characterized in that the (+) and the (-) pole is electrically connected to the second through-hole respectively different. The method of claim 2,
A leaf spring disposed below the connection board, the outer side of which is mounted to the first blade, and the inner side of which is mounted to the second blade to elastically support the second blade in the vertical direction; Including more,
An outer side of the leaf spring is electrically connected to the second through hole,
The inner side of the leaf spring is electrically connected to the second coil member and a small camera device, characterized in that to supply power to the second coil member. The method of claim 5, wherein
Guide grooves are formed in the outer circumferential surface of the second blade in the leaf spring direction,
The leaf spring is formed with a engaging groove in communication with the guide groove,
An end portion of the second coil member is inserted into the engaging groove along the guide groove is connected to the leaf spring ring. The method according to claim 1 or 2,
The first wire spring and the second wire spring is disposed in the vertical direction between the first blade and the second blade,
And a straight line distance between the first wire springs arranged in a diagonal direction is the same as a straight line distance between the second wire springs arranged in a diagonal direction. The method of claim 3, wherein
Four flat parts having a planar shape are formed to be spaced apart from each other on the outside of the second blade.
Four chamfers having a planar shape are formed to be integrally connected with the flat part between the flat parts.
The second coil member is wound along the flat portion and the chamfered portion,
The other end of the yoke member has a planar shape parallel to the plane portion and is disposed to face the second coil member wound on the plane portion.
Small camera device, characterized in that the extension line between the first wire spring and the second wire spring disposed adjacent to each other parallel to the chamfering portion.

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