KR100845334B1 - Device For Controlling Auto Convergence Of Small Optical Lens - Google Patents

Abstract

The present invention relates to an automatic focus control apparatus for a small optical lens using a linear DC motor, the lens assembly is a lens holder coupled to the inside of the bonded permanent magnet drive unit; and the upper side required to restore the drive unit to the initial position; It is configured to move the driving unit by applying a repulsive force to the bond permanent magnet by the magnetic force generated by the spring is formed of a spring and the lower spring and the coil is spaced apart so that there is no void space outside the bond permanent magnet, the coil of the magnetic circuit portion It provides an automatic focus control device for a small optical lens, which is installed on the outside and comprises an additional circuit part formed of a circular soft magnetic material that generates a bond permanent magnet and a new additional magnetic force by adding a magnetic force of a coil, and a housing for combining the units together. do.

The present invention can reduce the cost of the magnetic circuit portion by forming the magnetic circuit portion of the bond permanent magnet and coil in place of the upper, lower magnetic body and the sintered permanent magnet of precision machining, in particular to remove the thickness of the magnetic material inner plate of the prior art By using a thin bonded permanent magnet, not only can reduce the size of the product, but also reduce interference defects in manufacturing, and by adding an additional circuit portion of the soft magnetic material to generate additional magnetic force to reinforce the insufficient magnetic strength of the bonded permanent magnet There is an advantage that can increase the overall driving force.

Auto Focus, Auto Focus, Optical Lens, Actuator, Additional Circuit

Description

Device For Controlling Auto Convergence Of Small Optical Lens

1 is an exploded perspective view showing an automatic focus control apparatus for a compact lens according to the prior art.

2 is a cross-sectional view of the autofocus control device shown in FIG.

3 is an exploded perspective view showing an automatic focus adjusting apparatus for a compact optical lens according to the present invention.

4 is a cross-sectional view of an automatic focus adjusting apparatus for a compact optical lens according to the present invention.

Figure 5 is a magnetic flux pattern of the magnetic circuit portion showing the additional magnetic force of the bonded permanent magnet by the end effect in accordance with the present invention.

6 is a graph showing the magnetic force generated by the coil of the magnetic circuit unit according to the present invention.

7 is a graph showing the additional magnetic force generated by the magnetic force of the additional circuit portion according to the present invention.

8 is a graph showing the total driving force of the driving unit in the automatic focusing device of the compact optical lens according to the invention.

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

51: Lens Assembly 52: Top Cover

53: upper spring 54: housing

55 magnetic circuit section 55a coil

55b: Bond permanent magnet 56: Terminal

57: additional circuit portion 59: lens holder

60: spacer 61: lower spring

62: lower cover 80: automatic focusing device of a small optical lens

The present invention relates to an automatic focus adjusting apparatus for a compact optical lens, and more particularly, to an automatic focus adjusting apparatus for improving the structure of the magnetic circuit to reduce the product size and cost.

Digital cameras that can focus automatically require an automatic focusing device that can change the position of the lens. In general, an automatic focusing device for an optical lens used in a digital camera gears a stepping motor or a DC motor. A method of linearly moving a focus lens in the optical axis direction using a converter such as is widely used.

However, the auto focusing device of a small optical lens used in a confined space such as a camera module of a mobile phone is difficult to mount a rotary motor and a gearbox, such as a linear DC motor as shown in FIGS. 1 and 2. LDM) drive is used.

In addition, the linear DC motor type used in the automatic focusing device of a small optical lens is applied to both a moving coil type linear motor (Moving Coil Type LDM) and a moving magnet type linear motor (Moving Magnet Type LDM). However, since the permanent magnet is heavier than the coil and the weight of the movable part increases, the coil movable type as shown in FIG. 1 is preferred.

As shown in FIGS. 1 and 2, the conventional auto focus adjusting apparatus 20 for a compact optical lens includes a coil 9 mounted on a lens holder 10 in which a lens assembly 1 is coupled by a screw fastening method. It includes a drive unit, a magnetic circuit unit consisting of two soft magnetic bodies 6 and 8 and a ring-shaped permanent magnet 7, and upper and lower housings 3 and 13 fastened by four screws 2. It consists largely of fixed parts.

The linear motion of the conventional compact optical lens auto focusing device 20 is composed of two soft magnetic bodies 6 and 8 and a ring-shaped permanent magnet 7 to form a magnetic circuit part to form an inner plate of the upper magnetic body 6 ( A constant magnetic flux always flows in the gap between 6a) and the inner surface of the lower magnetic body 8, and an optical axial magnetic force generated when the current links with the magnetic flux by applying a current to the coil 9 located in the gap. Left hand law)

However, in the conventional automatic focus adjusting device, the inner plate 6a of the upper magnetic body is positioned between the lens holder 10 and the coil 9, thereby increasing the size of the product due to the thickness of the inner plate and the gap between both sides of the inner plate. In addition, there is a problem that interference occurs between the inner plate 6a of the upper magnetic body and the coil 9 or the lens holder 10 during operation. In addition, since the upper and lower magnetic bodies and sintered permanent magnets are required, the cost of the magnetic circuit part is high.

The present invention for solving the above problems is to reduce the cost of the magnetic circuit portion by forming the magnetic circuit portion of the bonded permanent magnet and coil at low cost and by adding an additional circuit portion of the soft magnetic material, the structure of the prior art By using the bonded permanent magnet that can remove the magnetic inner plate and make the thickness thin, it can not only reduce the size of the product significantly but also provide the automatic focus control device of the small optical lens that can reduce the manufacturing defects. The purpose is.

Another object of the present invention is to provide an automatic focus control device for a compact optical lens by increasing the driving force by providing an additional circuit portion of the soft magnetic material apart from the permanent magnet for the purpose of increasing the decreasing magnetic force by adopting a bonded permanent magnet. There is a purpose.

The automatic focusing device of the compact optical lens of the present invention for achieving the above objects uses a linear direct-current motor, the drive unit and the initial position of the drive unit in which the bond permanent magnet is mounted on the lens holder coupled to the lens assembly. It is configured to move the driving unit by applying a repulsive force to the bond permanent magnet by the magnetic force generated by the spring portion is formed spaced apart so that there is no void space to the outside of the bond permanent magnet and the spring portion consisting of the upper and lower leaf springs, It is configured to include a housing for coupling the unit parts together with an additional circuit unit formed of a circular soft magnetic material which is installed outside the coil of the magnetic circuit unit to add a magnetic force of the coil to generate a bond permanent magnet and a new additional magnetic force.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings.

First, as shown in FIGS. 3 to 4, the driving unit including the lens holder 59 having the lens assembly 51 coupled therein and the upper and lower plate springs 53 and 61 necessary for restoring the driving unit to the initial position. ) And the bond permanent magnet 55b is mounted on the driving unit, and a repulsive force is applied to the bond permanent magnet 55b by a magnetic force generated by the coil 55a spaced apart from the bond permanent magnet 55b to move the driving unit. The additional circuit unit 57 is installed outside the magnetic circuit unit 55 and the coil 55a of the magnetic circuit unit 55 to add a magnetic force of the coil 55a to generate a bond permanent magnet 55b and a new additional magnetic force. ) And an upper cover 52 for combining the terminal parts 56 for supplying current to both ends of the coil 55 copper wire, the spacer 60 for protecting the lead wire of the coil, and preventing the rotation of the lens into one. ), Housing 54, lower It consists of a side cover 62.

Here, the additional circuit portion 57 increases the amount of magnetic flux flowing through the coil 55 to increase the magnetic force, and additional drag force due to an end effect between the bond permanent magnet 55b and the additional circuit portion 57. Formed in contact with the outer side of the coil (55a) of the magnetic circuit portion 55 for the purpose of increasing the overall driving force, the material is to be formed of a soft magnetic material.

In addition, the terminal 56 is made of FPCB (FLEXIBLE PRINTED CIRCUITS BOARD) material, inserted into two bosses of the spacer 60, and fixed by thermal fusion, and the +,-lead wires of the coil 55a. It is preferable to connect to and supply a current.

The motor driving method of the magnetic circuit part is different from the coil movable type in which the upper and lower magnetic bodies 6 and 8 and the permanent magnet 7 are installed in the fixed part and the coil 9 is installed in the driving part. The magnet movable type which arrange | positions 55a and the additional circuit part 57, and the bond permanent magnet 55b by the drive part is used. Through this, the size of the magnetic circuit part 55 can be reduced by removing the thickness of the inner plate and the gaps on both sides of the inner plate 6a by removing the conventional upper magnetic inner plate 6a, and the upper magnetic inner plate 6a. The interference defect can be improved by eliminating the interference frequently generated in the gap between the coil 9 and the lens holder 10. In addition, it is possible to reduce the cost of the magnetic circuit unit 55 by removing the upper and lower magnetic bodies (6), (8) having a high cost because precision processing is required.

In addition, conventionally, one or several strong magnetic sintered permanent magnets 7 are mainly used. However, in the case of the sintered permanent magnet (7) it is difficult to manufacture a thin thickness, the size of the adjusting device is large, and if there is a curved shape, such as C-shaped or cylindrical, there is a problem of increasing the cost of the product high processing cost. In particular, the automatic focusing device 80 of a small optical lens adopting a magnet-driven motor driving method in which a magnet and a lens move together as in the present invention, when the sintered permanent magnet is adopted, the weight of the permanent magnet is heavy, thereby driving the lens. Can cause problems.

Therefore, in the present invention, the problem is solved by applying a bonded permanent magnet 55b which is inexpensive, light in weight, and thin in thickness. In addition, by utilizing the features that can be produced in a variety of shapes to form a bonded permanent magnet (55b) in the form of a cylindrical ring to contact the outer diameter of the lens holder 59 by adhering to increase the reliability of the permanent magnet (55b) to drop impact.

However, the magnetic circuit part 55 uses a bonded permanent magnet 55b having a weaker magnetic force than the sintered permanent magnet and removes the upper and lower magnetic bodies 6 and 8 forming the magnetic circuit part 55. There is a problem that the magnetic force in the circuit portion 55 is reduced. In order to solve this problem, increase the magnetic force generated in the coil 55a (the force caused by Fleming's left-hand law generated when current flows in the coil in the direction in which the magnetic flux is interlinked with the magnetic flux) and further magnetic force. This is necessary.

The additional circuit section 57 of the present invention is provided with an additional circuit section 57 made of a soft magnetic material to be in contact with the outer side of the coil 55 of the magnetic circuit section for the purpose of increasing the driving force reduced by the change of the magnetic circuit section.

The effect of the additional circuit portion 57 is to add a soft magnetic material in the magnetic circuit portion 55 to reduce the magnetic resistance of the magnetic circuit portion 55 to increase the amount of magnetic flux as shown in FIG. As the magnetic flux increases in this manner, as shown in FIG. 6, the magnetic force generated in the coil 55a is increased. In addition, an additional magnetic force generated by the end effect (longitudinal end effect) of the magnet-operated linear DC motor shown in FIG. 5 is generated at both ends of the additional circuit unit 57, and thus the repulsive force is applied to the bond permanent magnet 55b by the additional magnetic force of FIG. The total driving force used for driving the lens of the auto focusing device may be increased as shown in FIG. 8.

The additional magnetic force generated at both ends of the additional circuit unit 57 increases in proportion to the amount of movement of the bond permanent magnet 55b regardless of the amount of current in the coil 55a. Therefore, when the bond permanent magnet 55b starts to move by the magnetic force of the coil 55a generated by the current, an additional magnetic force in proportion to the amount of movement of the bond permanent magnet 55b is further generated to stably maintain the lens holder 59. Sufficient driving force to be driven can be obtained.

Referring to the assembly method and the operation of the present invention configured as described above in detail.

First, the driving unit is configured by mounting the bond permanent magnet 55b and the lens holder 59.

Then, the housing 54 is turned upside down to insert the additional circuit portion 57 and the coil 55a, and the driving portion is inserted into the coil 55a.

In addition, the spacer 60, the lower plate spring 61, and the lower cover 62 are sequentially mounted with the lower heat fusion boss of the housing 54 as a guide, and then the four bosses protruding are fixed by heat fusion. Next, turn the housing 54 combined with the single components, and install the upper plate spring 53 and the upper cover 52 in order with the upper heat fusion boss of the housing as a guide, and then heat the four protruding bosses. After fixing, and finally, the lead wire of the coil protruding out of the product is soldered to the terminal 56, the terminal 56 is inserted into two bosses protruding from the spacer 60, and heat-sealed to assemble the autofocus control device.

The up and down linear motion of the drive unit is generated by the magnetic force (Fleming's left hand law) generated in the coil 55a in the vertical direction when the current flows through the magnetic flux, and the coil 55a is fixed. As a result, the bond permanent magnet 55b moves.

At this time, when a magnetic force is applied to the bond permanent magnet 55b, the driving unit overcomes the elastic restoring force of the upper and lower leaf springs 53 and 61 to start the movement. Since the elastic restoring force of the upper and lower leaf springs 53 and 61 increases in proportion to the amount of movement, the displacement of the driving unit can be controlled by a magnetic force controlled by the amount of current flowing through the coil 55a.

In addition, when the movement of the driving unit occurs, the magnetic force of the additional circuit unit 57 is additionally generated in proportion to the amount of movement, thereby increasing the driving force reduced by the change of the magnetic circuit unit 55.

When the auto focus operation is completed and the voltage applied to the coil 55a is removed, the initial position is restored by the elastic force of the upper and lower plate springs 53 and 61 which hold down the driving unit.

As described above, the automatic focusing device of the compact optical lens of the present invention reduces the cost of the magnetic circuit part by forming the magnetic circuit part with the bonded permanent magnet and the coil in place of the upper, lower magnetic material and the sintered permanent magnet of precision machining. In particular, by using a bonded permanent magnet capable of removing the magnetic inner plate of the prior art and manufacturing a thin thickness, it is possible to reduce the size of the product as well as to reduce interference in manufacturing.

In addition, by adding an additional circuit portion of the soft magnetic material to generate an additional magnetic force can be reinforced the insufficient magnetic force of the bond permanent magnet can increase the overall driving force.

Claims (2)

A drive unit in which a bond permanent magnet is mounted to a lens holder coupled to the lens assembly; and a spring unit comprising an upper spring and a lower spring required to restore the driving unit to an initial position; and a void space outside the bond permanent magnet. It is configured to move the driving unit by applying a repulsive force to the bond permanent magnet by the magnetic force generated by the coil is spaced apart, and is installed outside the coil of the magnetic circuit portion to add the magnetic force of the coil to generate the bond permanent magnet and new additional magnetic force An additional circuit unit formed of a soft magnetic material of a circular shape; and an automatic focus control apparatus for a small optical lens consisting of a housing for combining the single parts into one. delete

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