KR100980044B1 - Compact camera device - Google Patents

Abstract

PURPOSE: A compact camera device is provided to connect a first elastic member with a first power connecting member, thereby facilitating assembly. CONSTITUTION: A first blade(400) moves up and down by a magnet and a first coil member. A first elastic member is electrically connected to a first coil member. The first elastic member elastically supports the up and down movement of the first blade. The first power connecting member(600), arranged in up and down directions of the first elastic member, supplies power to the first coil member. A contact protrusion is formed in one of the first elastic member or the power connecting member.

Description

Compact camera device {

The present invention relates to a compact camera apparatus, and more particularly, to a compact camera apparatus that adjusts the focus of a subject by moving a lens up and down using a coil and a magnet and corrects camera shake by moving in a horizontal direction.

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 It comprises a yoke member 60 disposed adjacent to (41).

 The first blade 40 is caused by 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 first coil member 41. The focus of the subject is adjusted by moving up and down with the lens.

The first blade 40 is equipped with a first elastic member 42 for elastically supporting the first blade 40 in the vertical direction.

The first elastic member 42 has an outer side mounted and fixed to the second blade 30 and an inner side mounted and fixed to the first blade 40 so that the first blade when the second blade 30 moves horizontally. Let 40 move together.

One end of the first elastic member 42 is mounted to the cover 20, and a contact protrusion 43 connected to an external power source is mounted on the first elastic member 42.

In addition, the first elastic member 42 is electrically connected to the first coil member 41 to transfer the power of the contact protrusion 43 to the first coil member 41.

Meanwhile, the second blade 30 is elastically supported in the horizontal direction by the 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.

However, when the second blade 30 moves horizontally, the first blade 40 moves in the horizontal direction together with the first elastic member 42, but the contact protrusion 43 is fixed to the cover 20. It does not move.

That is, when one end of the contact protrusion 43 is fixed to the cover 20 and does not move together when the second blade 30 moves horizontally, it prevents the movement of the second blade 30.

In order to solve this problem, the first extension part 43a and the second extension part bent from the first extension part 43a are formed in parallel with the outer surface of the second blade 30. It consisted of the part 43b.

The contact protrusions 43 formed of the first extension part 43a and the second extension part 43b are contracted and relaxed mutually when the second blade 30 is horizontally moved, so that the second blade 30 is disposed on the contact protrusion 43. The contact projections 43 were allowed to move smoothly without interference.

However, the first elastic member 42 having the contact protrusion 43 formed of the first extension part 43a and the second extension part 43b has a complicated shape and thus is difficult to manufacture and assemble.

In addition, when the second blade 30 is horizontally moved, the contact protrusion 43 is present as an element that hinders the movement of the second blade 30 because it must be elastically deformed at least.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and provides a compact camera device that simplifies the shape of the contact protrusion to facilitate manufacturing and assembly, and minimizes elements that hinder the horizontal movement of the second blade. There is a purpose.

In order to achieve the above object, the compact camera device of the present invention includes a housing, a first blade disposed inside the housing, including a lens therein, and moving up and down by a magnet and a first coil member; A compact camera device comprising a first elastic member electrically connected to a first coil member and supporting the first blade up and down, wherein the first elastic member is disposed in a vertical direction to supply power to the first coil member. It further comprises a first power supply connecting member for supplying, wherein any one of the first elastic member or the first power connecting member is formed with a contact projection is electrically connected to the other.

A second blade mounted inside the housing so as to move horizontally, horizontally and horizontally, and the first blade mounted vertically inside the housing; A second coil member mounted to a side of the second blade; Wherein the magnet is mounted to the housing adjacent to the second coil member, by the interaction of the electromagnetic field generated when the power applied to the second coil member and the magnetic field generated in the magnet Move the two blades in the horizontal, horizontal, horizontal direction, the first elastic member is fixed to the outer side of the upper or lower side of the second blade and the inner side is coupled to the first blade, the first power connection member is the housing The first elastic member is fixedly mounted to the first blade, and moves together with the second blade in a state in which the first elastic member is in contact with the first power connection member by the contact protrusion when the second blade is horizontally moved.

The contact protrusion is formed in the first elastic member, bent in the direction of the first power connection member is in contact with the first power connection member, one end is connected to the first elastic member and the other end is placed in a free state have.

The housing may include a first housing separated in an upward direction of the first blade; And a second housing separated in a lower direction of the first blade, wherein the first elastic member is mounted on an upper side of the first blade and disposed below the first housing, and the first power connection member Is mounted on the upper side of the first housing, the first power connection member is bent in the lower direction of the first housing is formed with a contact terminal in contact with the lower surface of the first housing and the other surface is in contact with the contact projection. .

A guide groove through which the contact terminal is inserted is formed at a side surface of the first housing, and the contact terminal includes: a connecting portion smaller than a nubber of the guide groove; It is larger than the width of the guide groove, is formed extending from the connecting portion, and is supported by the lower side of the first housing made of a copper plate portion in contact with the contact projections, protruding downward on both sides of the guide groove of the copper plate portion A locking step is formed in contact with the side to prevent the separation of the copper plate.

And a yoke member mounted to the housing so as to be in contact with the magnet, and having a magnetic induction protrusion adjacent to the first coil member through the second coil member and the second blade. The coil member is mounted on the side of the first blade to move the first blade up and down by the interaction between the electromagnetic field generated when the power is applied and the magnetic field of the magnet induced through the magnetic induction protrusion.

A second elastic member having one end mounted on the housing and the other end mounted on the second blade to elastically support the second blade in a horizontal direction; Wherein the second elastic member is one end is electrically connected to the first power connection member, the other end is electrically connected to the second coil member is connected to the first power supply to the second coil member Deliver power to the member.

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

The first elastic member is disposed in the vertical direction and further comprises a first power supply connecting member for supplying power to the first coil member, wherein the first elastic member or any one of the first power connecting member By forming protrusions and electrically connecting with the other one, the first elastic member is directly connected to the first power connection member to facilitate the assembly and simplify the overall structure without adding a separate component for power connection. There is.

The first elastic member has an outer side fixedly mounted on the upper side or the lower side of the second blade, the inner side is coupled to the first blade, and the first power connection member is fixedly mounted on the housing, so that the horizontal of the second blade When the first elastic member moves along with the second blade in a state in which the first elastic member is in contact with the first power connecting member by the contact protrusion, the first elastic member and the first power connecting member are moved in a horizontal movement of the second blade. There is an effect of reducing the interference by to facilitate the horizontal movement of the second blade.

The contact protrusion is formed in the first elastic member, bent in the direction of the first power connection member is in contact with the first power connection member, one end is connected to the first elastic member and the other end is placed in a free state As a result, even if the height between the first elastic member and the first power connection member is different, the contact protrusion easily contracts and relaxes, thereby facilitating the connection with the first power connection member, and weakening the elastic force of the contact protrusion. It is effective to minimize friction with the first power connection member.

The first power connection member is bent in a downward direction of the first housing so that one surface is in contact with the lower surface of the first housing and the other surface is in contact with the contact protrusion, whereby the contact terminal is connected to the lower side of the first housing. It is supported by the side to prevent the bending when in contact with the contact projections, there is an effect of improving the contact force between the contact terminal and the contact projections.

Protruding downwardly on both sides of the guide groove to form a locking step in contact with the side of the copper plate, thereby preventing the copper plate from moving in the side direction so that the copper plate does not leave the guide groove.

And a yoke member mounted to the housing so as to contact the magnet and having a magnetic induction protrusion penetrating the second coil member and the second blade to be adjacent to the first coil member. The member is mounted on the side of the first blade to move the first blade up and down by interaction between the electromagnetic field generated when the power is applied and the magnetic field of the magnet induced through the magnetic induction protrusion, thereby separate for vertical movement It has the effect of simplifying the overall structure by enabling both horizontal movement and shanghai movement with one magnet without the magnet of.

One end of the second elastic member is electrically connected to the first power connection member, and the other end is electrically connected to the second coil member to transfer power of the first power connection member to the second coil member. Simplifies the overall structure by performing both the function of elastically supporting the second blade up and down and the function of transferring power to the second coil member without a separate component for transmitting power to the second coil member. It is effective to let.

3 is a perspective view of a compact camera device according to an embodiment of the present invention, Figure 4 is a one-way exploded perspective view of the compact camera device according to an embodiment of the present invention, Figure 5 is a compact camera device according to an embodiment of the present invention 6 is an exploded perspective view of another direction, FIG. 6 is a diagram illustrating a coupling state of the first blade, the second blade, and the first elastic member of the present invention, and FIG. It is a coupling state diagram.

3 to 7, the compact camera apparatus of the present invention includes a housing 100, a magnet 200, a yoke member 300, a first blade 400, a first coil member 450, and a first coil. It comprises an elastic member 500, the first power connection member 600, the second blade 700, the second coil member 750, the second elastic member 800 and the second power connection member 900. .

The housing 100 has a hexahedron shape and includes a first housing 110 separated in an upper direction of the first blade 400 and a second housing 120 separated in a lower direction of the first blade 400. Is done.

The first housing 110 has a rectangular plate shape and protrudes downwardly at the sides near the edges, and the second housing 120 has a rectangular plate shape protruding upwards at the sides near the edges. It is coupled to the side of the first housing 110.

In addition, an outer surface of the housing 100 is mounted with a cover 180 surrounding the upper surface of the first housing 110 and the outer surfaces of the first housing 110 and the second housing 120. Protect.

In addition, openings 130 through which incident light from a lens passes are formed in the first housing 110 and the second housing 120, respectively, and the first power connection member 600 is formed on the side surface of the first housing 110. Guide groove 140 through which the connecting portion 611 of the insertion is formed.

The guide groove 140 has a quadrangular shape, and a total of two guide grooves 140 are formed, one on each side of the first housing 110 which is symmetrical to each other.

In addition, the locking jaw 150 protruding downward is formed on both sides of the guide groove 140 in the lower portion of the first housing 110.

In addition, the magnet 200 is inserted into and mounted to the side of the first housing 110 and the side of the second housing 120.

The magnet 200 is disposed to face up and down on the first housing 110 and the second housing 120 in a rectangular shape, respectively, the first housing 110 and the second housing 120, respectively. It consists of 8 pieces of 4 pieces each.

 In addition, the yoke member 300 is mounted between the magnet 200 disposed in the first housing 110 and the magnet 200 disposed in the second housing 120.

The polarity of the magnet 200 is formed in the vertical direction, the magnet 200 is mounted to the first housing 110 and the second housing 120, respectively, the polarity of the yoke member 300 It is arranged symmetrically up and down.

That is, when the magnet 200 mounted on the first housing 110 is disposed with the S pole in the upward direction and the N pole is disposed in the downward direction, the magnet 200 mounted in the second housing 120 is upward. The north pole is arranged and the south pole is disposed downward.

The yoke member 300 is formed of a ferromagnetic material in a rectangular shape, and the upper and lower surfaces thereof are mounted on the side of the housing 100 to be in contact with the magnet 200.

The yoke member 300 is formed with a magnetic induction protrusion 310 to guide the magnetic field of the magnet 200 in a predetermined direction.

The magnetic induction protrusion 310 protrudes in the direction of the first coil member 450 as described below, and is adjacent to the first coil member 450 in the direction of the first coil member 450. Induce a magnetic field of 200).

The first blade 400 and the second blade 700 are mounted in the housing 100.

Specifically, the second blade 700 is mounted in a hollow shape of a hexahedron such that the first blade 400 is moved up and down.

In addition, the second blade 700 includes a support member 710 in contact with a lower surface of the first blade 400 to support the first blade 400 not to move downward.

The support member 710 may be fixed to the lower side of the second blade 700 and may be integrally formed with the second blade 700 in some cases.

In addition, the second coil member 750 is mounted on an outer surface of the second blade.

The second coil member 750 is a wire through which a current flows therein and is wound in a direction orthogonal to a winding direction of the first coil member 450 as described below, one on each side of the second blade 700. A total of four are mounted.

In addition, the second blade 700 is mounted to the front, rear, left and right horizontal movement in the lower portion of the first housing 110 by the second elastic member (800).

The second elastic member 800 is made of a wire spring, one end is mounted to the first housing 110 and the other end is mounted to the support member 710 of the second blade 700 to the second blade Resilient support in the horizontal direction in the support state (700).

Four second elastic members 800 are mounted on the support member 710 in a diagonal direction.

In addition, the second elastic member 800 is made of an electrically conductive material, and is electrically connected to the second coil member 750 to transfer power to the second coil member 750.

In detail, a second power connection member 900 electrically connected to the second coil member 750 is mounted below the second blade 700.

The second power connection member 900 has a quadrangular shape and is formed at the center of the upper and lower sides thereof, and each of the corner portions has a copper foil hole in which the second elastic member 800 and the second coil member 750 are electrically coupled and fixed. 910 is formed.

The copper foil hole 910 facilitates connection of the second elastic member 800 and the second coil member 750 by allowing a conductive adhesive such as lead or paste to adhere well.

As described above, one end of the second elastic member 800 is mounted to the first housing 110 to be electrically connected to the first power connection member 600, and the other end of the second elastic member 800 is mounted to the support member 710. As the second power connection member 900 is electrically connected, power of the first power connection member 600 may be transmitted to the second coil member 750.

In addition, the second elastic member 800 reduces the overall number of parts by performing both a function of vertically and elastically supporting the second blade 700 and a function of transferring power to the second coil member 750. It is effective to simplify.

On the other hand, the first blade 400 has a hexahedron shape, the upper and lower open holes are formed in the center thereof, and the lens is mounted therein.

In addition, the first coil member 450 is mounted on an outer surface of the first blade 400.

The first coil member 450 is a thin wire having a current flowing therein and is wound around the outer surface of the first blade 400.

In addition, the first coil member 450 is adjacent to the magnetic induction protrusion 310 of the yoke member 300.

In detail, the magnetic induction protrusion 310 protruding toward the first coil member 450 from the yoke member 300 mounted on the side surface of the first housing 110 has a side surface of the second blade 700. A side of the second coil member 750 and the second blade 700 mounted in the through and adjacent to the first coil member 450.

The first coil member 450 moves up and down the first blade 400 by the interaction between the electromagnetic field generated when the power is applied and the magnetic field of the magnet 200 induced through the magnetic induction protrusion 310. The focus of the subject incident on the lens mounted on the first blade 400 is adjusted by moving.

As described above, the yoke member 300 penetrates the second coil member 750 and the second blade 700 to form a magnetic induction protrusion 310 adjacent to the first coil member 450. Without a separate magnet 200 for the movement, it is possible to enable both the horizontal movement and the Shanghai movement in one magnet 200.

In addition, the first elastic member 500 is mounted on the upper side of the first blade 400, and the third elastic member 560 is mounted on the lower side of the first blade 400 to vertically support the first blade 400.

The third elastic member 560 has a thin plate shape, the outside of which is fixed to the support member 710, and the inside of the third elastic member 560 is mounted to the lower side of the first blade 400 so that the first blade 400 is vertically up and down. Elastic support.

The first elastic member 500 is made of a material that is electrically conductive in a thin plate shape, as shown in Figure 6, the outside is mounted fixed to the upper side of the second blade 700, the inside is the first blade Is coupled to the upper side of the 400 to move the first blade 400 up and down inside the second blade (700).

In addition, the outer side of the first elastic member 500 mounted on the upper side of the second blade 700 is fixed by fusion or adhesive, etc., the first elastic member mounted on the upper side of the first blade 700 ( The inner side of the 500 is in close contact with the spacer member 550 and fixed to the first blade 700.

In addition, the outer side and the inner side of the first elastic member 500 are elastically connected to each other, it is possible to shrink and relax in the vertical direction.

The first elastic member 500 is formed to be separated on both sides with respect to the first blade 400 and the outer side of the separated first elastic member 500 is electrically connected to the first power connection member 600. Contact protrusions 510 are connected to each other,

The contact protrusion 510 has a long rectangular shape, the center portion of which is bent toward the first power connection member 600 to be in contact with the first power connection member 600.

In addition, as shown in FIG. 6, one end of the contact protrusion 510 is integrally connected to the first elastic member 500, and the other end is bent once again horizontally with the first elastic member 500. The upper surface of the first blade 400 is placed in a free state.

When the contact protrusion 510 is pressed downward, the bent portion is relaxed, and is elastically supported toward the first power connection member 600 by the elastic restoring force of the bent portion to connect the first power source. In contact with the member 600.

As described above, the contact protrusion 510 is formed on the first elastic member 500, and is bent in the direction of the first power connection member 600 to be in contact with the first power connection member 600. The contact protrusion 510 is connected to the first elastic member 500 and the other end is set in a free state, even if the height between the first elastic member 500 and the first power connection member 600 is different. Easily contracted and relaxed to facilitate the connection with the first power connection member 600, and to reduce the friction with the first power connection member 600 by weakening the elastic force of the contact projection 510.

Meanwhile, the first power connection member 600 is connected to an external power source to supply power to the first coil member 450 and the second coil member 750.

Specifically, the first power connection member 600 is made of a flexible circuit board (FPCB) in a rectangular thin plate shape, and is mounted on the upper side of the first housing 110.

Contact terminals 610 in contact with the contact protrusion 510 are formed to protrude on both sides of the first power connection member 600, respectively.

The contact terminal 610 is bent in the lower direction of the first housing 110 as surrounding the side of the first housing 110 in the first power connection member 600, as shown in FIG. One surface is in contact with the lower surface of the first housing 110 and the other surface is in contact with the contact protrusion 510 to electrically connect the first power connection member 600 and the first elastic member 500.

In this way, the first elastic member 500 is disposed in the vertical direction further comprises a first power connection member 600 for supplying power to the first coil member 450, the first elastic member ( By forming the contact protrusion 510 on the 500 to be electrically connected to the first power connection member 600, the first elastic member 500 directly contacts the first elastic member 500 without adding a separate component for power connection. 1 is connected to the power connection member 600 to facilitate the assembly and has the effect of simplifying the overall structure.

In addition, although the contact terminal 610 is in contact with the contact protrusion 510, the external force acts upward by the contact protrusion 510, the contact terminal 610 is the lower side of the second housing 120 Do not bend or move because it is in contact with and supported.

In some cases, the contact terminal 610 may be formed on the first elastic member 500, and the contact protrusion 510 may be formed on the first power connection member 600.

As described above, the first power connection member 600 is bent in the lower direction of the first housing 110 so that one surface is in contact with the lower surface of the first housing 110 and the other surface is in contact with the contact protrusion 510. The terminal 610 is formed so that the contact terminal 610 is supported by the lower surface of the first housing 110 to prevent bending when contacting the contact protrusion 510 and prevents the contact terminal 610 from contacting the contact terminal 610. There is an effect of improving the contact force of the contact protrusion 510.

In addition, the contact terminal 610 is formed in the connecting portion 611 smaller than the width of the guide groove 140, the connection portion 611 and the copper plate portion 612 larger than the width of the guide groove 140 It is made, including.

The connection part 611 is made of a flexible material and easily bent, and is bent in the lower direction of the first housing 110 to surround the side of the first housing 110 by inserting the guide groove 140.

At this time, the connecting portion 611 is spaced apart at regular intervals so as not to contact the side of the first housing 110 in which the guide groove 140 is formed, and is gently bent to prevent the connecting portion 611 from being damaged.

The copper plate part 612 is made of a material in which current flows, and when the contact with the contact protrusion 510 is performed, external power is transmitted to the contact protrusion 510.

In addition, the width of the copper plate portion 612 is formed larger than the moving distance of the contact protrusion 510 is always in contact with the copper plate portion 612 even if the contact protrusion 510 is moved horizontally.

In addition, the copper plate portion 612 is in contact with the side surface of the locking step 150 formed on both sides of the guide groove 140.

The locking jaw 150 protrudes further downward than the copper plate portion 612, and the width of the locking jaw 150 is formed to be narrower than the width of the copper plate portion 612, similar to the guide groove 140. When it moves in the horizontal direction it is in contact with the locking projections (150).

As such, by forming the locking projections 150 protruding downward on both sides of the guide groove 140 and contacting the side surfaces of the copper plate part 612, the copper plate part 612 is prevented from moving in the side direction. In order to prevent the copper plate part 612 from being separated from the guide groove 140.

The following describes the operation state of the compact camera device of the present invention.

8 and 9 are top and bottom operating state diagrams of the compact camera device according to the embodiment of the present invention as seen from BB of FIG. 3, and FIGS. 10 and 11 are compact camera devices according to the embodiment of the present invention as seen from CC of FIG. 3. Is a horizontal operation state diagram.

As shown in FIG. 8, before the first blade 400 moves up and down, the lower side of the first blade 400 contacts the upper side of the support member 710 to prevent movement downward. The magnetic induction protrusion 310 is disposed slightly downward from the center of the first coil member 450.

In addition, the first elastic member 500 is mounted on the upper side of the first blade 400 to elastically support the first blade 400 is not moved upward.

In addition, the copper plate part 612 of the contact terminal 610 is supported not to be bent in the vertical direction in contact with the lower side of the cover, it is in contact with the contact projection 510.

As shown in FIG. 9, when power is applied to the first coil member 450, an electromagnetic field generated by the first coil member 450 and a magnetic field of the magnet 200 induced from the magnetic induction protrusion 310. By the interaction with the first blade 400 is moved upwards.

The first blade 400 moves until the magnetic induction protrusion 310 is adjacent to the lower portion of the first coil member 450, and the first elastic member 500 has an inner side of the second blade ( The outside fixed to the first blade 400 without moving fixedly to the 700 moves upward with the first blade 400.

Accordingly, the first elastic member 500 is relaxed between the inside and the outside, and the first elastic member 500 elastically supports the first blade 400 downward by an elastic restoring force.

In addition, since the contact protrusion 510 is disposed outside the first elastic member 500 and does not move, the contact protrusion 510 continuously contacts the contact terminal 610.

In addition, when the direction of the power applied to the first coil member 450 is reversely applied, the first blade 400 moves downward until the first blade 400 contacts the support member 710. Move.

Meanwhile, as shown in FIG. 10, before the second blade 700 moves in the horizontal direction, the second blade 700 is suspended from the upper portion of the base by hanging on the second elastic member 800. The second elastic member 800 is vertical and the magnetic induction protrusion 310 is disposed at the center of the second coil member 750.

In addition, the contact protrusion 510 is disposed in the center portion of the contact terminal 610 in a horizontal direction, the bent portion is electrically connected to the first power connection member 600 in contact with the contact terminal 610. .

In addition, an upper end of the second elastic member 800 is connected to the first power connection member 600, and a lower end of the second elastic member 800 is connected to the second power connection member 900 together with the disconnection of the second coil member 750. It is miraculously connected to transfer the power of the first power connection member 600 to the second coil member 750.

As shown in FIG. 11, when power is applied to the second coil member 750, the second blade 700 may include the second coil member 750, the second power connection member 900, and the second coil member 750. The horizontal member moves horizontally with the lower end of the elastic member 800.

An upper end of the second elastic member 800 is mounted on the first housing 110 and does not move, and a lower end of the second elastic member 800 is mounted on the support member 710 of the second blade 700 to expand to the left. .

The second elastic member 800 is elastically supported in the right direction by the elastic restoring force.

In addition, the contact protrusion 510 is horizontally moved to the left side together with the second blade 700 in contact with the contact terminal 610 so that the first elastic member 500 and the first power connection member 600 are moved. Maintain electrical connection to the unit.

In addition, according to the direction of the power applied to the second coil member 750 it is possible to move horizontally to the right, also horizontal movement in the front and rear direction.

As described above, when the front, rear, left, and right horizontal movements of the second blade 700 move, the first elastic member 500 is in contact with the first power connection member 600 by the contact protrusion 510. By moving together, the horizontal movement of the second blade 700 by reducing the interference by the first elastic member 500 and the first power connection member 600 during the horizontal movement of the second blade 700 is easy. It's effective.

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 an exploded perspective view of a conventional compact camera device,

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 one-way exploded perspective view of a compact camera device according to an embodiment of the present invention;

5 is an exploded perspective view of another direction of the compact camera device according to the embodiment of the present invention;

6 is a state diagram of the coupling of the first blade and the second blade and the first elastic member of the present invention,

7 is a state diagram of the coupling of the first housing, the first power supply connecting member and the first elastic member of the present invention,

8 and 9 are diagrams showing the vertical operation of the compact camera device according to the embodiment of the present invention as seen from B-B of FIG.

10 and 11 are horizontal operating state diagrams of the compact camera device according to the embodiment of the present invention as seen from C-C of FIG.

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

100: housing, 200: magnet, 300: yoke member, 310: magnetic induction protrusion 400: first blade, 450: first coil member, 500: first elastic member, 510: contact protrusion, 600: first power connection member 610: contact terminal, 700: second blade, 750: second coil member, 800: second elastic member, 900: second power connection member,

Claims (7)

A first blade disposed inside the housing and including a lens therein, the first blade being vertically moved by a magnet and a first coil member, and electrically connected to the first coil member and being electrically connected to the first blade; In the small camera device comprising a first elastic member for supporting the elastic up and down, Is disposed in the vertical direction of the first elastic member further comprises a first power connection member for supplying power to the first coil member, Any one of the first elastic member or the first power connection member is formed with a contact projection is characterized in that the small camera device characterized in that it is electrically connected to the other. The method of claim 1, A second blade mounted inside the housing so as to move horizontally, horizontally and horizontally, and the first blade mounted vertically inside the housing; A second coil member mounted to a side of the second blade; It is made, including more The magnet is mounted to the housing adjacent to the second coil member and horizontally moves the second blade forward, backward, left, and right by an interaction between an electromagnetic field generated when power is applied to the second coil member and a magnetic field generated by the magnet. Move to, The first elastic member is fixed to the outer side of the upper or lower side of the second blade and the inner side is coupled to the first blade, The first power connection member is fixedly mounted to the housing to move together with the second blade in a state in which the first elastic member is in contact with the first power connection member by the contact protrusion when the second blade is horizontally moved. Small camera device, characterized in that. The method according to claim 1 or 2, The contact protrusion is formed in the first elastic member, bent in the direction of the first power connection member is in contact with the first power connection member, one end is connected to the first elastic member and the other end is placed in a free state Small camera device characterized in that. The method of claim 3, wherein The housing, A first housing separated in an upward direction of the first blade; It comprises a second housing which is separated in the lower direction of the first blade, The first elastic member is mounted on the upper side of the first blade and disposed below the first housing, The first power connection member is mounted on the upper side of the first housing, The first power connecting member is bent in the lower direction of the first housing, the compact camera device, characterized in that the contact surface is formed in contact with the lower surface of the first housing and the other surface is in contact with the contact projection. The method of claim 4, wherein A guide groove through which the contact terminal is inserted is formed at the side of the first housing, The contact terminal, A connecting portion smaller than the nubber of the guide groove; It is larger than the width of the guide groove, is formed extending from the connecting portion, and is made of a copper plate that is supported on the lower side of the first housing in contact with the contact projection, Small camera device protruding in the lower direction on both sides of the guide groove is formed in contact with the side of the copper plate portion to prevent the separation of the copper plate portion. The method of claim 2, And a yoke member mounted to the housing so as to contact the magnet and having a magnetic induction protrusion penetrating the second coil member and the second blade to be adjacent to the first coil member. The first coil member is mounted on the side of the first blade to move the first blade up and down by the interaction between the electromagnetic field generated when the power is applied and the magnetic field of the magnet induced through the magnetic induction protrusion. Compact camera device. The method of claim 2, A second elastic member having one end mounted on the housing and the other end mounted on the second blade to elastically support the second blade in a horizontal direction; It is made, including more One end of the second elastic member is electrically connected to the first power connection member, and the other end is electrically connected to the second coil member to transfer power of the first power connection member to the second coil member. Small camera device characterized in that.

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