KR20220048867A - Light source module - Google Patents

Abstract

The present invention relates to a light source module to provide increased operation efficiency. According to the present invention, the light source module comprises: a shutter unit provided with conductive ink containing conductive particles; a light source unit disposed on the lower part of the shutter unit; an electromagnet und disposed on a side part of the shutter unit and spaced apart from the light source unit; and a magnet disposed on a side part of the shutter unit and disposed adjacent to the light source unit. When current is not applied to the electromagnet unit so that the electromagnet unit is in a non-magnetized state, the conductive ink moves towards the magnet due to a magnetic force acting between the conductive particles and the magnet to cover the upper part of the light source unit. When a current is applied to the electromagnet unit so that the electromagnet unit is in a magnetized state, the conductive ink moves toward the electromagnet unit by a magnetic force acting between the conductive particles and the electromagnet unit to open the upper part of the light source unit, thereby exposing the light source unit.

Description

Light source module {LIGHT SOURCE MODULE}

The present invention relates to a light source module, and more particularly, to a light source module for controlling whether a light source attached to an electrical/electronic device is exposed.

Recently, camera modules have been mounted on various types of electric and electronic devices such as automobiles as well as portable devices such as smart phones and tablet computers. Such a camera module is used for various purposes, such as a photographing operation of a photo and a video, object recognition, or biometric recognition.

In such a camera module, a photographing operation is performed at a time desired by a user regardless of time and place. Therefore, along with the camera module, a light source module for supplementing insufficient light depending on the shooting time or surrounding environment is also provided.

The light source module includes a light source such as a light emitting diode (LED), and is separately driven by a user's selection operation in association with the operation of the camera module or regardless of the operation of the camera module to turn on the light source.

In this case, since the light source needs to finally irradiate light to a desired part, it is always exposed to the outside of the device in which the light source module is mounted.

Since such a light source module is driven only at a specific time or a user's selection operation, such as at night, the operation frequency is relatively low compared to other modules or devices such as a camera module.

However, as already described, the light source module is always exposed to the outside of the device regardless of whether it is operating or not, thereby impairing the aesthetics of the device. Contamination may adversely affect the amount of light output.

Korean Patent Laid-Open Patent No. 10-2008-0099003 (Publication date: November 12, 2008, title of invention: Auxiliary optical device for LED package and light emitting device including the same)

SUMMARY OF THE INVENTION An object of the present invention is to improve the aesthetics of an electrical/electronic device equipped with an optical module.

Another problem to be solved by the present invention is to protect the optical module from foreign substances.

An optical module according to one aspect of the present invention for solving the above problems is a shutter unit having a conductive ink containing conductive particles, a light source unit located under the shutter unit, a light source unit located below the shutter unit, a side portion of the shutter unit, and spaced apart from the light source unit an electromagnet and a magnet positioned on the side of the shutter, and positioned adjacent to the light source; It moves toward the magnet by the magnetic force acting between the magnets to cover the upper part of the light source part, and when a current is applied to the electromagnet part and the electromagnet part is in a magnetized state, the conductive ink acts between the conductive particles and the electromagnet part It moves toward the electromagnet part by the magnetic force to open the upper part of the light source part to expose the light source part.

The electromagnet unit may be one.

The electromagnet unit may be positioned opposite to the magnet to face the magnet.

The electromagnet unit may have a ring shape that seamlessly surrounds the light source unit and the magnet.

The shutter unit includes a first transparent substrate positioned above the light source unit, a second transparent substrate positioned on the first transparent substrate, and the first transparent substrate and the second transparent substrate between the first transparent substrate and the second transparent substrate; It may include a spacer positioned in contact.

The spacer may have a ring shape that is continuously connected to edges of the first transparent substrate and the second transparent substrate, and the conductive ink is applied to the first transparent substrate, the second transparent substrate, and the spacer. It may be located in a space surrounded by

The shutter portion is located on one side of the first transparent substrate and the second transparent substrate, a first clip for applying pressure to the first transparent substrate and the second transparent substrate, and the first transparent substrate and the second transparent substrate It may further include a second clip positioned on the other side of the first and second transparent substrate for applying pressure to the transparent substrate.

The first clip and the second clip may include two mounting parts respectively mounted on the first transparent substrate and the transparent substrate, and a connecting part connected between the two mounting parts and having a bent middle part.

The number of the electromagnet parts may be two.

The electromagnet part may include a first electromagnet part positioned on a lower surface of the first transparent substrate and a second electromagnet part positioned on an upper surface of the second transparent substrate to face the first electromagnet part, and the first The electromagnet part and the second electromagnet part may be positioned to face each other.

When the first magnet and the second magnet are in a magnetized state, a repulsive force may act between the first magnet and the second magnet facing each other.

The optical module according to the above characteristics may further include a first coating film and a second coating film located on the surface of the first transparent substrate and the surface of the second transparent substrate in contact with the conductive ink, respectively, and having water-repellent or oil-repellent properties there is.

The optical module according to the above feature may further include a base substrate on which the light source unit is positioned.

The electromagnet unit may be located on the base substrate.

The optical module according to the above feature may further include an upper housing positioned above the shutter unit and having a window through which the light source unit is exposed.

The conductive ink may have an opaque color.

According to this feature, when the operation of the optical module is not made, since the shutter part located on the upper part of the optical module covers the upper part of the light source part, the light source part is not exposed to the outside.

Accordingly, the mounting position of the light source to the electrical and electronic device is not recognized from the outside, and the aesthetics of the electrical and electronic device is improved.

In addition, since the light source unit is not exposed to the outside while the optical module is not in operation, the degree of contaminating the light source surface by attaching foreign substances such as dust to the light source surface is greatly reduced. Accordingly, the amount of loss of output light that varies according to the degree of contamination of the surface of the light source is also reduced, and thus the operating efficiency of the light source module is improved.

In addition, since the light source is not exposed to the outside when it is not in operation, the case where the light source is damaged or damaged due to an impact applied from the outside is greatly reduced.

In addition, the mobility of the conductive ink, which obstructs the exposure of the light source, is improved, so that the user's convenience is improved.

1 is a perspective view of an optical module according to an embodiment of the present invention, (a) is a perspective view when the light source is covered, (b) is a perspective view when the light source is exposed to the outside.
FIG. 2 is an exploded perspective view of the optical module shown in FIG. 1 .
3 is a partial cross-sectional view obtained by omitting the lower housing when the optical module according to an embodiment of the present invention is cut along any one direction, (a) is a cross-sectional view when the electromagnet unit is in a non-magnetized state, (b) is It is a cross-sectional view when the electromagnet part is in a magnetized state.
4 is an exploded perspective view of an optical module according to another embodiment of the present invention.
5 is a partial cross-sectional view obtained by omitting the lower housing when the optical module according to another embodiment of the present invention is cut in one direction, (a) is a cross-sectional view when the electromagnet unit is in a non-magnetized state, (b) is It is a cross-sectional view when the electromagnet part is in a magnetized state.
6 is an exploded perspective view of an optical module according to another embodiment of the present invention.
7 is a partial cross-sectional view obtained by omitting the lower housing when the optical module according to another embodiment of the present invention is cut in one direction, (a) is a cross-sectional view when the electromagnet unit is in a non-magnetized state, (b) is a cross-sectional view when the electromagnet unit is in a magnetized state.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that adding a detailed description of a technique or configuration already known in the relevant field may make the gist of the present invention unclear, some of it will be omitted from the detailed description. In addition, the terms used in this specification are terms used to properly express embodiments of the present invention, which may vary according to a person or custom in the relevant field. Accordingly, definitions of these terms should be made based on the content throughout this specification.

The terminology used herein is for the purpose of referring to specific embodiments only, and is not intended to limit the invention. As used herein, the singular forms also include the plural forms unless the phrases clearly indicate the opposite. As used herein, the meaning of 'comprising' specifies a particular characteristic, region, integer, step, operation, element and/or component, and other specific characteristic, region, integer, step, operation, element, component, and/or group. It does not exclude the existence or addition of

Hereinafter, an optical module according to an embodiment of the present invention will be described with reference to the accompanying drawings.

First, a light source module 1 according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3 .

1 to 3 , the optical module 1 of this example includes a lower housing 11 , a base substrate 20 positioned on the lower housing 11 , and an electromagnet unit 30 positioned on the base substrate 20 . ), the magnet 40 located on the base substrate 20, the light source unit 50 located on the base substrate 20, the shutter unit 60 located on the light source unit 50, the control unit located on the base substrate 20 70 and an upper housing 12 positioned on the shutter unit 60 and coupled to the lower housing 11 may be provided.

In this example, the lower housing 11 and the upper housing 12 are combined with each other to form an empty space therein, and the components 20 to 70 constituting the optical module 1 may be located in the formed empty space. there is.

The lower housing 11 may have a substantially rectangular (eg, rectangular) planar shape.

The upper part of the lower housing 11 is open, so it is possible to obtain an empty space enclosed by the lower surface and the side part inside.

The electromagnet unit 30 and the light source unit 50 mounted on the base substrate 20 may be located in the inner space of the lower housing 11 .

In this example, one side of the lower housing 11, that is, one of the two sides facing each other along the extending direction (eg, transverse direction) X of the lower housing 11, may be opened without being blocked laterally. there is. Accordingly, a portion of the base substrate 20 may be exposed through the open side of the lower housing 11 .

The base substrate 20 may be located on the lower surface of the lower housing 11 , as previously described. In this case, the base substrate 20 may be stably mounted on the lower surface of the lower housing 11 through an adhesive or the like.

The base substrate 20 may be formed of a flexible substrate such as a flexible printed circuit board (FPCB), but is not limited thereto.

In this example, the base substrate 20 is, as shown in FIG. 2 , a substrate body 21 having a substantially rectangular planar shape and one longitudinal side of the substrate body 31 , that is, extending in the width direction (Y). It may be provided with a connecting portion 22 that is vertically bent downward from one side and exposed to the outside.

An electromagnet unit 30 , a magnet 40 , and a light source unit 50 may be mounted on the upper surface of the substrate body 21 .

The connection part 22 may be exposed to the outside through the open vertical side of the lower housing 11 positioned below.

When the upper housing 12 is coupled to the lower housing 11 , a part of the connection part 22 may be exposed to the outside. A signal input/output operation to the base substrate 30 may be performed through the exposed end of the connection part 22 .

The base substrate 20 includes a plurality of signal lines and pads for electrical and physical connection between electric and electronic devices such as the light source unit 50, the electromagnet unit 30, and the control unit 70 positioned on the corresponding surface. can do.

Accordingly, signal transmission between electrical and electronic devices and input/output of signals to the corresponding electrical and electronic devices can be performed through the signal line and the pad.

In addition, as previously described, an input/output operation of signals to and from the outside may be performed through the connection part 32 exposed on the open side of the lower housing 11 .

The electromagnet unit 30 may function as a magnet generating a magnetic field by determining whether to be magnetized by a signal (ie, current) applied from the control unit 70 , and maintaining the magnetization state while the current is applied.

Therefore, the electromagnet unit 30 controls the operation of the shutter unit 60 located adjacently according to whether such magnetization is performed, and controls the light source unit 50 to be exposed to the outside when in a magnetized state, and vice versa when in a non-magnetized state. It is possible to control so that the light source unit 50 is not exposed to the outside.

As shown in FIG. 3 , the electromagnet unit 30 may be located adjacent to the edge of the shutter unit 60 , and may be separated from the light source unit 50 and the magnet 40 located together on the base substrate 20 . can be spaced apart.

2 and 3 , the electromagnet unit 30 may be located opposite the light source unit 50 . Accordingly, the electromagnet unit 30 is located adjacent to one side (eg, the left side) of the substrate body 21 of the base substrate 20 facing each other in the extension direction X, and the light source unit 50 is located at one side and may be located adjacent to the other side (eg, the right side) of the substrate body 21 facing from the opposite side.

At this time, since the electromagnet unit 30 is spaced apart from the outer surface of the shutter unit 60 , the electromagnet unit 30 may protrude up to a height at which the shutter unit 60 is located.

The magnet 40 may be located on the base substrate 20 on the same side as the electromagnet unit 30 , that is, the substrate body 21 , and with the electromagnet unit 30 located on the opposite side in the extension direction (X) and can be positioned face to face.

Accordingly, the magnet 40 may be positioned adjacent to the light source unit 50 , and thus, the light source unit 50 may be positioned between the electromagnet unit 30 and the magnet 40 .

Unlike the electromagnet unit 30 , the magnet 40 is a permanent magnet that always has magnetism, and the strength of the magnetic force may be smaller than the strength of the magnetic force when the electromagnet unit 30 is magnetized.

Therefore, when the state of the electromagnet unit 30 is switched from the magnetized state to the non-magnetized state, the magnet 40 uses its own magnetic force to restore the state of the shutter unit 60 to the initial state, It is possible to control so that the light source unit 50 is not exposed to the outside through the shutter unit 60 .

The magnet 40 may be mounted on the shutter unit 60 , and in this case, it may be located adjacent to the light source unit 50 .

The light source unit 50 may include a light source 51 that is turned on or off according to the state of the driving signal applied from the control unit 70 .

In this case, the light source 51 may be a light emitting diode (LED).

As already described, whether the magnetization of the electromagnet unit 30 is determined according to whether the light source unit 50 is turned on or not, and the magnetization control of the electromagnet unit 30 is performed by a metal wire (ie, a coil) constituting the electromagnet unit 30 . It may be current application.

Accordingly, the control unit 70 may control the application of current to the electromagnet unit 30 according to the state of the driving signal applied to the light source unit 50 .

The shutter unit 60 changes its operating state according to the magnetization state of the electromagnet unit 30 so that the light source unit 50 located below can be recognized from the outside.

The shutter unit 60 may be located on the upper side of the side of the lower housing 11 , and as shown in FIGS. 2 and 3 , the upper transparent substrate 61 and the lower transparent substrate sequentially positioned under the upper housing 12 . (62), the spacer 63 positioned between the upper transparent substrate 61 and the lower transparent substrate 62, and conductive ink positioned in the empty space between the upper transparent substrate 61 and the lower transparent substrate 62 (64) may be provided.

Both the upper transparent substrate 61 and the lower transparent substrate 62 may have the same structure, and may be made of a transparent and hard material such as transparent glass or transparent plastic.

Since these transparent substrates 61 and 62 are located on the upper side of the side of the lower housing 11 as already described, the length of the side extending in the width direction Y from each of the transparent substrates 61 and 62 is the lower housing 11 ) may be the same as the extension length of the corresponding side surface (ie, the side located on the longitudinal side).

However, the length of the side surface extending in the extension direction X from each of the transparent substrates 61 and 62 may be shorter than the extension length of the corresponding side surface (ie, the side surface positioned on the horizontal side) of the lower housing 11 .

Accordingly, the open upper part of the lower housing 11 is not covered with the shutter part 60 and there is an open part, and the electromagnet part 30 and the part of the substrate body 21 corresponding to the open part are present. The magnets 40 are positioned and may be positioned adjacent to the side surfaces of the shutter units 60 facing each other.

In an alternative example, when the magnet 40 is located in the shutter unit 60, the shutter unit 40 is one side of the lower transparent substrate 52, that is, the light source unit ( 50) and may be located on the adjacent side. Even in this case, the light source unit 50 may be positioned between the electromagnet unit 30 and the magnet 40 .

A spacer 63 may be positioned between the upper transparent substrate 61 and the lower transparent substrate 62 that are positioned in the thickness direction of the optical module 1 and face each other.

Accordingly, the upper transparent substrate 61 and the lower transparent substrate 62 may be spaced apart by a distance determined by the thickness of the spacer 63 , and the conductive ink 64 may be moved through this space.

As shown in FIG. 2 , the spacers 63 of this example are seamlessly connected and have a ring shape such as a square having an empty space in the middle, and face each other and face the upper transparent substrate 61 and the lower part. It is positioned at the edge of the transparent substrate 62 .

For this reason, in the shutter unit 60, a closed space surrounded by the upper transparent substrate 61, the lower transparent substrate 62, and the spacer 63 positioned in contact with each other (hereinafter, the enclosed space is 'space for ink)' ') (S60) is generated, and the fluid conductive ink 54 may be located in the space S60 for ink. Accordingly, the spacer 63 may perform a dam function to limit the movement range of the conductive ink 54 .

The conductive ink 64 includes particles 641 of a conductive material, such as a metal such as gold (Au), silver (Ag), platinum (Pt), piladium (Pd), copper (Cu), or nickel (Ni). It may be a flowable ink.

In addition, the conductive ink 64 of this example may contain a dye of an opaque color such as black, and thereby the conductive ink 64 may have an opaque color such as black. Accordingly, when the conductive ink 64 is positioned on the light source unit 50 , the light source unit 50 is not exposed to the outside.

The conductive ink 64 generates a magnetic force (eg, attractive force) between the electromagnet part 30 and the electromagnet part 30 due to the conductive material contained therein when the electromagnet part 30 is in a magnetized state. At this time, as already described, since the strength of the magnetic force of the electromagnet unit 30 is greater than that of the magnet 40 , the conductive ink 64 positioned adjacent to the magnet 40 is formed with the upper transparent substrate 61 and It may move in the first direction X1 toward the electromagnet unit 30 through the empty space between the lower transparent substrates 62 .

For the movement of the conductive ink 64 according to the magnetization of the electromagnet unit 30 , the inner surface (eg, lower surface) of the upper transparent substrate 61 and the inner surface of the lower transparent substrate 62 facing each other (eg, the upper surface) may be provided with coating films 611 and 621 using a material of nano-sized particles, or the like.

In this case, the material forming the coating layers 611 and 621 may be determined according to the characteristics of the conductive ink 64 .

For example, when the conductive ink 64 has water-soluble properties, the coating layers 611 and 621 may contain a water-repellent material to have water-repellent properties.

In addition, when the conductive ink 64 has oil-soluble properties, the coating layers 611 and 621 may contain an oil-repellent material to have oil-repellent properties.

As described above, as the coating films 611 and 621 are respectively located on the inner surfaces of the upper transparent substrate 61 and the lower transparent substrate 62 in contact with the conductive ink 64, the conductive ink 64 is in contact with the upper transparent substrate. It is possible to quickly move in the corresponding direction without leaving any residue on the inner surfaces of the 61 and the lower transparent substrate 62 .

Accordingly, the corresponding surfaces of the upper transparent substrate 61 and the lower transparent substrate 62 that are in contact with the conductive ink 64 can maintain their initial state without decreasing transparency even after the conductive ink 64 has been moved.

For this reason, the light source unit 50 covered by the conductive ink 64 can be exposed to the outside through the transparent portions of the lower transparent substrate 62 and the upper transparent substrate 61 by the movement of the conductive ink 64 . there is.

The control unit 70 located on the base substrate 20 is for controlling the operations of the electromagnet unit 30 and the light source unit 50 as described above, and the electromagnet unit 30 located thereon through the base substrate 20 . and electrically and physically connected to the light source unit 50 .

The upper housing 12 may be combined with the lower housing 11 to form an empty space therein, as described above.

The upper housing 12 has an open lower portion and may have a rectangular (eg, rectangular) planar shape having a side surface and an upper surface.

A window 121 exposing the light source unit 50 may be provided on the upper surface of the upper housing 12 , and the window 121 of the upper housing 12 may be positioned to face the light source unit 50 located below. can

Accordingly, when the conductive ink 64 moves toward the electromagnet unit 30 , the light source unit 50 exposed through the lower transparent substrate 62 and the upper transparent substrate 61 of the shutter unit 60 closes the window 121 . Since the light source 51 is exposed to the outside through the window 121 and the irradiated surface of the light source 51 is also exposed to the outside through the window 121, the light can be irradiated in a desired direction.

In the light source module 1 having such a structure, the control unit 70 may determine whether the light source 51 of the light source unit 50 should be turned on according to a user's motion or ambient illuminance.

When the state of the optical module 1 is determined to be an undriven state in which the light source 51 of the light source unit 50 is turned off by the operation of the control unit 70 , the control unit 50 controls the signal applied to the electromagnet unit 30 . (ie, current) is stopped or the current is not applied to the electromagnet unit 30 is maintained. Under the control of the control unit 70 , the electromagnet unit 30 may be in a non-magnetized state that is not driven.

As such, when the electromagnet unit 30 is in a non-magnetized state, by the magnetic force acting between the magnet 40 and the conductive ink 54 adjacent to the light source unit 50 , the conductive ink 54 is transferred to the light source unit 50 . is moved in the second direction X2.

Therefore, since the opaque conductive ink 54 is located on the light source unit 50, the light source unit 50 located under the transparent substrates 52 and 51 from the outside is exposed to the outside due to the excellent light blocking properties of the conductive ink 54. It is not exposed (Fig. 1 (a)).

However, when the light source 51 of the light source unit 50 needs to be turned on according to the user's operation or the surrounding environment, the control unit 70 applies a current to the electromagnet unit 30 to magnetize the electromagnet unit 30 . can do it

Due to the magnetization state of the electromagnet unit 30 , a magnetic force is generated between the electromagnet unit 30 and the conductive ink 64 , and the strength of this magnetic force is the magnetic force acting between the magnet 40 and the conductive ink 64 . greater than the century of Accordingly, the conductive ink 64 may move in the first direction X1 toward the electromagnet unit 30 .

As such, as the conductive ink 64 located on the upper portion of the light source unit 50 moves toward the electromagnet unit 30 , the light source unit 50 is exposed through the transparent substrates 52 and 51 located thereon, and the transparent substrate 52 . , 51 , the light source unit 50 exposed through the window 121 of the upper housing 12 may be exposed to the outside (FIG. 1 (b)).

In this way, in a state in which the light source unit 50 is exposed to the outside, when the light source 51 of the light source unit 50 is turned on by a driving signal applied from the control unit 70 , the light irradiated from the light source 51 is transmitted to the window 121 . ) through which it can be irradiated to the outside normally.

As such, since the electromagnet unit 30 is magnetized only when the light source unit 50 is turned on to expose the light source unit 50 to the outside, the esthetic of the electric/electronic device provided with the optical module 1 of the present example is improved.

In addition, in the optical module 1 of this example, since the light source unit 50 is always covered by the transparent substrates 52 and 51 , the light source 51 having the light irradiation surface is protected from foreign substances.

In this example, since exposure of the light source unit 50 is controlled using the conductive ink 64 that reacts by magnetic force rather than a complicated mechanical structure, the structure of the light source module 1 is simplified.

In an alternative example, the optical module 1 may further include a flicker sensor (not shown) positioned adjacent to the light source unit 50 . In this case, the flicker detection unit may be connected to the control unit 70 , and an operation state may be controlled according to the control of the control unit 70 .

The control unit 70 may determine whether flicker occurs when the light source 51 is turned on by using a detection signal applied from the flicker detection unit, and may output a driving signal for correcting the generated flicker to the light source unit 50 . In this case, since a correction operation for flicker is performed, the quality of light irradiated from the light source unit 50 is improved.

Next, an optical module 1a according to another embodiment of the present invention will be described with reference to FIGS. 4 and 5 .

In the following embodiment, compared with the optical module 1 shown in FIGS. 1 to 3, components having the same structure and performing the same function are given the same reference numerals as in the optical module 1, and A detailed description is also omitted.

As shown in FIG. 4 , the optical module 1a of this example may have a structure similar to that of the optical module 1 of FIGS. 1 to 3 , except for the electromagnet part 30a.

That is, the optical module 1a of this example also includes the lower housing 11 , the base substrate 20 positioned on the lower housing 11 , the electromagnet part 30a positioned on the base substrate 20 , the magnet 40 , and the light source part 50, the shutter unit 60 located on the light source unit 50, the control unit 70 located on the base substrate 20, and the upper housing 12 located above the shutter unit 60 and coupled to the lower housing 11 can be provided.

At this time, the shutter unit 60 includes an upper transparent substrate 61 , a lower transparent substrate 62 , a spacer 63 for separating the space between the upper transparent substrate 61 and the lower transparent substrate 62 , and the spacing A conductive ink 64 that is positioned between the spaces and whose position changes depending on whether the electromagnet unit 30a is magnetized may be provided.

However, in the optical module 1a of this example, the electromagnet unit 30a has a ring shape that seamlessly surrounds the light source unit 50 and the magnet 40, unlike the electromagnet unit 30 of FIGS. In this case, the metal wire may be wound in a ring shape from the edge of the corresponding surface (eg, the upper surface) of the substrate body 21 of the base substrate 20 .

In this case, the light source unit 50 and the control unit 70 may be located in a portion of the substrate body 21 surrounded by the electromagnet unit 30a , and the light source unit 50 may be located adjacent to the magnet 40 .

The shutter unit 60 may also be located in a space surrounded by the electromagnet unit 30a.

As described above, in a state in which the metal wire of the electromagnet unit 30a is wound around the edge of the substrate body 21 , when a current is applied to the electromagnet unit 30a, the conductive ink 64 moves in a predetermined direction (that is, the first direction (X1) or the second direction (X2)], but may move in all directions within the space between the upper transparent substrate 61 and the lower transparent substrate 62 surrounded by the spacer 63 .

That is, as shown in Fig. 5 (a), when the electromagnet unit 30a is in a non-magnetized state in which no current is applied to the electromagnet unit 30a, as already described with reference to Figs. Due to the magnetic force between the magnet 40 and the conductive ink 64 , the conductive ink 64 may move toward the magnet 40 , that is, in the second direction X2 . Accordingly, the conductive ink 64 is positioned on the light source unit 50 located adjacent to the magnet 40 to cover the upper portion of the light source unit 50 (refer to FIG. 5A ).

Accordingly, the light source unit 50 whose upper portion is covered with the conductive ink 64 having an opaque color is not exposed to the outside through the window 121 of the upper housing 12 .

However, when a current is applied to the electromagnet unit 30a under the control of the controller 90 and the electromagnet unit 30 is in a magnetized state, a magnetic force is generated between the electromagnet unit 30a and the conductive ink 64 , The strength of the magnetic force between the stone portion 30a and the conductive ink 64 may be greater than the strength of the magnetic force between the magnet 40 and the conductive ink 64 as previously described.

Accordingly, the conductive ink 64 concentrated toward the magnet 40 moves toward the electromagnet part 30a in a magnetized state. At this time, since the electromagnet part 30a surrounds the shutter part 60, the conductive ink 64 ) is scattered in all directions and moves toward the adjacent electromagnet part 30a, that is, toward the edge of the shutter part 60 (refer to FIG. 5(b)).

As such, as the conductive ink 64 located on the upper portion of the light source unit 50 moves toward the edge of the shutter unit 60 , the light source unit 50 is exposed through the lower transparent substrate 62 and the upper transparent substrate 61 . and thus exposed to the outside through the window 121 of the open upper housing 12 .

Accordingly, the light source 51 of the light source unit 50 that is turned on according to the control of the controller 70 may stably irradiate light to the outside through the window 121 .

Compared to FIGS. 1 to 3 , when the electromagnet unit 30 is magnetized, the moving direction of the conductive ink 64 is determined not in one direction but in several directions, so that the moving speed of the conductive ink 64 is greatly improved. An additional effect occurs.

Next, an optical module 1b according to another embodiment of the present invention will be described with reference to FIGS. 6 and 7 .

The optical module 1b according to this example may have the same structure as the optical module 1 of FIGS. 1 to 3 except for the electromagnet parts 31 and 32 and the shutter part 60b.

Accordingly, the optical module 1b of this example includes the lower housing 11, the base substrate 20 positioned in the lower housing 11, the electromagnets 31 and 32, the magnet 40 and the light source unit 50, the light source unit ( 50) may include a shutter unit 60b positioned above, a control unit 70 positioned on the base substrate 20 , and an upper housing 12 positioned above the shutter unit 60b and coupled to the lower housing 11 .

The shutter unit 60b of this example also includes an upper transparent substrate 61, a lower transparent substrate 62, a spacer 63b for separating the space between the upper transparent substrate 61 and the lower transparent substrate 62, and the spacing A conductive ink 64 that is positioned between the spaces and whose position changes depending on whether the electromagnet 30b is magnetized may be provided.

The electromagnet units 31 and 32 of the present example may have different mounting positions and numbers compared to the electromagnet units 30 of the optical module 1 .

That is, all of the electromagnet units 31 and 32 of this example may be plural (eg, two), and one of them, the first electromagnet unit 31 , may be mounted on the upper surface of the upper transparent substrate 61 . and the second electromagnet part 32 , which is the other one, may be mounted on the lower surface of the lower transparent substrate 62 .

The first electromagnet unit 31 and the second electromagnet unit 32 may be mounted on the corresponding substrates 61 and 62 using an adhesive or the like, and face each other from opposite sides with the transparent substrates 61 and 62 interposed therebetween. can be positioned

The first electromagnet unit 31 and the second electromagnet unit 31 are also connected to the control unit 70 through the base substrate 90 , and whether or not to be magnetized may be determined according to a control signal applied from the control unit 70 . there is.

When magnetizing the first electromagnet unit 31 and the second electromagnet unit 32 , the control unit 70 controls the direction of the current applied to the first electromagnet unit 31 and the current applied to the second electromagnet unit 32 . can be controlled in opposite directions.

For this reason, when the first electromagnet part 31 and the second electromagnet part 32 are in a magnetized state, the position of the polarity (N pole and S pole) generated in the first electromagnet part 31 and the second electromagnet part ( The positions of the polarities (N pole and S pole) generated in 32 are opposite to each other, and the first electromagnet part 31 and the second electromagnet part 32 facing each other with the transparent substrates 61 and 62 interposed therebetween. ), a repulsive force may act between them.

In addition, the shutter unit 60b of this example has an upper transparent substrate 61 and a lower transparent substrate in addition to the above-described upper transparent substrate 61, lower transparent substrate 62, spacer 63b, and conductive ink 64. A first clip 651 and a second clip 652 for changing the spacing of 62 may be additionally provided. Additionally, the spacer 63b of the shutter portion 60b may be made of a flexible material whose compression state is changed by applied pressure.

Accordingly, the thickness of the spacer 63b may increase or decrease depending on the state of the first clip 651 and the second clip 652, and due to the change in the thickness of the spacer 63b, the upper transparent substrate 61 The distance between the and the lower transparent substrate 62 may also be increased or decreased.

The first clip 651 and the second clip 652 may be mounted on the outside, that is, on the side of, the edges of the upper transparent substrate 61 and the lower transparent substrate 62 that are positioned to face each other in the top and bottom, respectively.

At this time, the first clip 651 and the second clip 652 may be positioned to face each other in opposite directions. It may be mounted, and the second clip 652 may be mounted outside the right edge of the other side of the shutter unit 60b.

The first clip 651 and the second clip 652 have the same shape as each other, and as shown in FIGS. 6 and 7 , may be formed of a leaf spring in which the middle part is bent.

As shown in FIG. 7 , the first clip 651 and the second clip 652 may be mounted at a corresponding position in a left and right inverted form.

Accordingly, the first clip 651 and the second clip 652 are between the two mounting parts 6511 and the two mounting parts 6511 respectively positioned in contact with the upper transparent substrate 61 and the lower transparent substrate 62, respectively. It is connected to and may include a connection part 6512 in which the middle part is bent outward.

Accordingly, the first clip 6511 and the second clip 6512 may apply pressure to the upper transparent substrate 61 and the lower transparent substrate 62 at the mounted positions.

At this time, depending on the force applied from the outside, the degree of bending of the connection part 6512 changes, thereby changing the pressure on the upper transparent substrate 61 and the lower transparent substrate 62, the first clip 651 and the second clip ( 652 may change the spacing between the upper transparent substrate 61 and the lower transparent substrate 62, respectively.

In the optical module 1b having this structure, when the first electromagnet part 31 and the second electromagnet part 32 are in a non-magnetized state in an undriven state, the first electromagnet part 31 and the second electromagnet part ( 32), there is no magnetic force between them.

Therefore, since the compressive strength of the first clip 651 and the second clip 652 compressing the upper transparent substrate 61 and the lower transparent substrate 62 is maintained in the initial state without change, the upper transparent substrate 61 The spacing between the lower transparent substrate 62 and the lower transparent substrate 62 also maintains the initial spacing.

In addition, when the first electromagnet unit 31 and the second electromagnet unit 32 are in a non-magnetized state, by the magnet 40 adjacent to the light source unit 50 , the magnet 40 and the conductive ink 54 . A magnetic force is generated therebetween, and the conductive ink 54 may move toward the light source unit 50 , that is, in the second direction X2 .

Therefore, as shown in (a) of FIG. 7 , the light source unit 50 located under the transparent substrates 61 and 62 is covered with the conductive ink 54 located thereon so that it is not exposed to the outside.

However, under the control of the controller 70, current is applied to the first electromagnet part 31 and the second electromagnet part 32 in the corresponding direction, respectively, so that the first electromagnet part 31 and the second electromagnet part 32 When the false magnetization state is reached, a magnetic force acting between the first and second electromagnets 31 and 32 and the conductive ink 64 may be formed.

At this time, since the strength of the magnetic force acting between the respective electromagnets 31 and 32 and the conductive ink 64 is greater than the magnetic force acting between the magnet 40 and the conductive ink 64, the conductive ink 64 is The first electromagnet unit 31 and the second electromagnet unit 32 may move in a first direction X1, which is a direction.

As such, when the electromagnets 31 and 32 are non-magnetized, the conductive ink 64 located on the upper portion of the light source 50 moves toward the first and second electromagnets 31 and 32 , so the light source 50 is disposed thereon. It may be exposed to the outside through the positioned transparent substrates 52 and 51 and the window 121 of the upper housing 12 (FIG. 7(b)).

Accordingly, the light source 51 of the light source unit 50 may radiate light in a desired direction through the open window 121 .

At this time, as shown in (b) of FIG. 7 , when the first electromagnet part 31 and the second electromagnet part 32 are in a magnetized state, they face each other with the transparent substrates 61 and 62 interposed therebetween. The electromagnet part 31 and the second electromagnet part 32 have the same polarity (eg, N pole).

Therefore, a repulsive force acts between the first electromagnet part 31 and the second electromagnet part 32 , and the connection part 6512 of the first clip 651 and the second clip 652 by this repulsive force. ) of the bending degree, that is, the bending angle increases from the initial state, so that the compression strength of the first clip 651 and the second clip 651 applied to the upper transparent substrate 61 and the lower transparent substrate 62 can be decreased. there is.

Due to the reduction in the compressive strength of the first clip 651 and the second clip 651, the thickness of the flexible spacer 23b increases in proportion to the reduced compressive strength, so that the upper transparent substrate 61 and the lower transparent substrate The separation interval of (62) may be increased compared to the initial state.

Due to the increase in the spacing between the upper transparent substrate 61 and the lower transparent substrate 62, the mobility of the conductive ink 64 located between the upper transparent substrate 61 and the lower transparent substrate 62 is further increased, The moving speed of the conductive ink 64 can be greatly improved.

In the state of the first clip 651 and the second clip 652 , when the first electromagnet part 31 and the second electromagnet part 32 change to a non-magnetized state, the conductive ink 64 is deposited as previously described. It moves in the second direction X2 where the magnet 40 is located and covers the upper portion of the light source unit 50 .

In addition, since the repulsive force between the first electromagnet part 31 and the second electromagnet part 32 disappears, the degree of bending of the first clip 651 and the second clip 652 is restored to the initial state, and the spacer ( The thickness of 63b) can also be returned to the initial state.

1 to 7, the amount of the conductive ink 64 positioned in the space S60 for ink is determined by the mounting position of the light source unit 50, the distance between the light source unit 50 and the magnet 40, and the upper It may be determined according to at least one of the spacing between the transparent substrate 61 and the lower transparent substrate 62 .

In addition, the position of the light source unit 50 located adjacent to the magnet 40 may also be changed in the substrate body 21 as needed, and a window ( 121) can also be changed.

The present invention is not limited to the above-described embodiments and the accompanying drawings, and various modifications and variations will be possible from the point of view of those of ordinary skill in the art to which the present invention pertains. Accordingly, the scope of the present invention should be defined not only by the claims of the present specification, but also by those claims and their equivalents.

1, 1a, 1b: optical module 11: lower housing
12: upper housing 121: window
20: base substrate 21: substrate body
22: connection part 30, 30a, 31, 32: electromagnet part
40: magnet 50: light source unit
60, 60b: shutter unit 61: upper transparent substrate
62: lower transparent substrate 63, 63b: spacer
64: conductive ink 611, 621: coating film
641: conductive particles 651, 652: clip
X1: first direction X2: second direction
S60: space for ink

Claims (16)

a shutter unit comprising conductive ink containing conductive particles;
a light source located under the shutter unit;
an electromagnet unit located on a side of the shutter unit and spaced apart from the light source unit; and
A magnet positioned on the side of the shutter unit and adjacent to the light source unit
including,
When no current is applied to the electromagnet and the electromagnet is in a non-magnetized state, the conductive ink moves toward the magnet by the magnetic force acting between the conductive particle and the magnet to cover the upper part of the light source,
When a current is applied to the electromagnet unit and the electromagnet unit is in a magnetized state, the conductive ink moves toward the electromagnet unit by a magnetic force acting between the conductive particles and the electromagnet unit to open the upper part of the light source unit. exposing
optical module. According to claim 1,
The electromagnet is a single optical module. 3. The method of claim 2,
The electromagnet unit is an optical module positioned to face the magnet from the opposite side of the magnet. 3. The method of claim 2,
The electromagnet unit has a ring shape that seamlessly surrounds the light source unit and the magnet. According to claim 1,
The shutter unit,
a first transparent substrate positioned above the light source unit;
a second transparent substrate positioned on the first transparent substrate; and
A spacer positioned between the first transparent substrate and the second transparent substrate in contact with the first transparent substrate and the second transparent substrate
An optical module comprising a. 6. The method of claim 5,
The spacer has a ring shape positioned to be seamlessly connected to the edge portions of the first transparent substrate and the second transparent substrate,
The conductive ink is located in a space surrounded by the first transparent substrate, the second transparent substrate and the spacer.
optical module. 6. The method of claim 5,
The shutter unit,
a first clip positioned on one side of the first transparent substrate and the second transparent substrate to apply pressure to the first transparent substrate and the second transparent substrate; and
A second clip positioned on the other side of the first transparent substrate and the second transparent substrate to apply pressure to the first transparent substrate and the second transparent substrate
An optical module further comprising a. 8. The method of claim 7,
The first clip and the second clip each include two mounting parts mounted on the first transparent substrate and the transparent substrate, respectively, and a connection part connected between the two mounting parts and having a bent middle part. 8. The method of claim 7,
The number of the electromagnet is two optical module. 10. The method of claim 9,
The electromagnet unit,
a first electromagnet located on a lower surface of the first transparent substrate; and
A second electromagnet unit positioned to face the first electromagnet unit on an upper surface of the second transparent substrate
including,
The first electromagnet unit and the second electromagnet unit are positioned to face each other. 11. The method of claim 10,
When the first magnet and the second magnet are in a magnetized state, a repulsive force acts between the first magnet and the second magnet facing each other. 6. The method of claim 5,
A first coating film and a second coating film positioned on the surface of the first transparent substrate and the surface of the second transparent substrate in contact with the conductive ink, respectively, and having water-repellent or oil-repellent properties
An optical module further comprising a. According to claim 1,
The light source module further comprising a base substrate on which the light source unit is located. 14. The method of claim 13,
The electromagnet unit is a light source module located on the base substrate. According to claim 1,
An upper housing positioned above the shutter unit and having a window exposing the light source unit
An optical module further comprising a. According to claim 1,
The conductive ink is an optical module having an opaque color.

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