KR101953178B1 - Mirror with light - Google Patents

Abstract

[0001] The present invention relates to a decorative lighting mirror in which LEDs emit light with uniform illuminance inside, and more particularly, to a decorative lighting mirror in which a plurality of LED modules are disposed in a mirror, a part of the reflective material is removed from the mirror glass, The present invention relates to a decorative mirror in which a light emitted from an LED is transmitted through a region to be visually recognized by a user.

Description

Decorative Mirror {MIRROR WITH LIGHT}

[0001] The present invention relates to a decorative lighting mirror in which LEDs emit light with uniform illuminance inside, and more particularly, to a decorative lighting mirror in which a plurality of LED modules are disposed in a mirror, a part of the reflective material is removed from the mirror glass, The present invention relates to a decorative mirror in which a light emitted from an LED is transmitted through a region to be visually recognized by a user.

Generally, an illuminating mirror with a lighting function in a mirror is generally manufactured by attaching a plurality of incandescent lamps or fluorescent lamps on both sides of a mirror frame. In recent years, instead of incandescent lamps and fluorescent lamps, lighting mirrors have also been fabricated that use LEDs to reduce power consumption.

Such a conventional LED illuminating mirror does not need to use a separate lighting device, and it has an advantage of consuming very little electric power because it uses an LED, but since it is a method of directly lighting by an LED light source installed on the front surface of a mirror, The light of the bulb enters directly into the field of view, causing eye fatigue, dispersing the mind, and a shadow on the face or object reflected on the mirror.

In many cases, the use of a mirror installed in a bathroom or a sauna is often a problem. Water vapor generated in the use of a bathroom or a sauna interferes with the use of the mirror due to condensation on the surface of a mirror having a low temperature. Several techniques are known to prevent this mirror from being fogged.

First, there is a technique of circulating hot water used in a bathroom or a sauna through a pipe provided on the rear surface of the mirror to raise the surface temperature of the mirror. However, such a method involves installation of separate piping for circulating hot water, so that a lot of piping installation costs and time are required, and it takes a long time to prevent the fogging of the mirror surface by circulating the actual hot water .

There is also a technique for preventing condensation of water vapor by providing a heating wire such as a nichrome wire on the rear surface of the mirror and raising the surface temperature of the mirror using the heating wire. However, in such a technique, it is necessary to arrange the heating wires at regular intervals on the rear surface of the mirror. Moreover, since the heating wires are used, there is a risk of overheating due to malfunction, And discoloration of a mirror portion attached to the mirror.

1. Registered utility model No. 20-0465860 'Mirror with LED light' (filed on Dec. 18, 2012) 2. Open Patent Publication No. 10-2013-0031461 'Illumination Mirror with Anti-fogging Function' (filed on September 21, 2011) 3. Registered Patent Publication No. 10-1685140, 'Advertising Light Mirror' (Filing date 2015.07.10)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a decorative lighting mirror capable of providing a room interior effect as well as a relatively reduced glare due to the transmission of light having a smooth illuminance inside a mirror .

In addition, the present invention can prevent moisture from being formed on the surface of a mirror by using heat generated from the LED module, and it is possible to increase the convenience of the user by attaching a separate switch for ON / OFF of the LED module Decorative lighting mirrors.

The decorative lighting mirror according to the present invention includes a support plate 110 having a predetermined thickness and protrusions formed at predetermined intervals in a direction intersecting a side surface of the support plate 110 along an edge of the support plate 110, A housing (100) comprising a side plate (120) defining a receiving space (S); An LED 210 disposed in the accommodation space S and adjacent to an inner side surface of the side plate 120 to emit light emitted from the center of the support plate 110 by being supplied with power from the outside, LED module 200; A reflection plate 300 which is fixed to an edge of the side plate 120 to seal the accommodation space S and to which a reflective coating layer 310 is applied so as to reflect an external object on one exposed side; A controller 400 connected to the LED module 200 to control light emission of the LED 210; And a controller 500 connected to the controller 400 and controlling brightness, hue, and light emission of the LED 210 according to an operation of the controller 400. The reflective coating layer 310 includes And is applied except for a region that is arbitrarily set so that the light of the LED 210 emitted from the inside of the housing 100 passes through the outside.

An air inlet hole 121 through which external air flows into the housing 100 is formed at one side of the side plate 120 and the inside of the housing 100 is connected to the reflector 300, The LEDs 210 are arranged in the housing 100. The LEDs 210 are connected to the air outlet holes 301 through the air outlet holes 301. The air holes 301 are communicated with each other through the air outlet holes 301, And an inner partition 600 separating between the side plate 120 and the LED module 200 to prevent moisture from being formed on the surface of the reflective plate 300 while being in contact with the surface of the LED module 300 .

The inner partition wall 600 may include a first circulation path 610-1 adjacent to the side plate 120 between the inner side of the side plate 120 and the LED module 200, A first inner partition wall 610 for partitioning the LED module 200 and the adjacent first to second circulation path 610-2; A second 2-1 circulation path 620-1 adjacent to the side plate 120 and a second 2-2 circulation path 620-2 adjacent to the LED module 200 are arranged symmetrically with the first inner partition wall 610, A second inner partition wall 620 partitioning the second inner partition wall 620; A first guide partition wall 630 extending from one end of the first inner partition wall 610 and guiding air introduced into the air inlet hole 121; And a second guide partition wall 640 which is symmetrical with the first guide partition 630 and extends from one end of the second inner partition wall 620 to guide air introduced into the air inlet hole 121 do.

In the present invention, the first 1-1 ring circuit 610-1, the 1-2 ring circuit 610-2, the 2-1 ring circuit 620-1, the 2-2 ring circuit 620-2, A branch hole 650 is formed between the other end of the first inner partition wall 610 and the other end of the second inner partition wall 620 so that the LED 210 emits light, When the existing air is heated, the heated air passes through the branch hole 650 along the 1-2 circulation path 610-2 and the 2-2 circulation path 620-2 and flows through the 1-1 circulation path 610 -1) and the second-1 circulation path 620-2, and is discharged to the air discharge hole 301.

In addition, in the present invention, the first 1-1 circulation path 610-1 and the second 1-1 circulation path 620-2 may be provided with a first air discharge hole 1 reverse flow preventing rib 700 protruding from the first circulation path 610-1 and the second circulation path 620-2 with a predetermined radius of curvature in the direction of the moving air.

The present invention is advantageous in that the light emitted from the LED module is not directly irradiated to the user, thereby preventing the user's glare, and can be used as an ornamental product for the interior of the interior.

In addition, the present invention can provide a function of preventing moisture from being formed on the surface of a mirror, in addition to a lighting function, through heat generated when an LED module performing a lighting function generates heat.

In addition, the present invention improves the usability of the LED module by adjusting the intensity of light emitted from the LED module according to the position of the user and a touch button that can turn on / off the LED module.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing an overall appearance of a decorative lighting mirror according to the present invention. FIG.
2 is an exploded perspective view showing a main configuration of a decorative lighting mirror according to the present invention;
3 is a cross-sectional view illustrating the interior air circulation structure of the decorative lighting of the present invention in winter;
4 is a side view showing an air circulation state of the decorative lighting mirror according to the present invention.
5 is a sectional view showing another embodiment of the decorative lighting mirror of the present invention.
6 is an exploded perspective view showing another embodiment of the decorative lighting mirror of the present invention.
7 is a perspective view showing another embodiment of the decorative lighting mirror of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a decorative illumination mirror according to the present invention will be described in detail with reference to the drawings.

FIG. 1 is a perspective view showing an overall configuration of a decorative lighting mirror according to the present invention, FIG. 2 is an exploded perspective view showing a main configuration of the decorative lighting mirror according to the present invention, and FIG. 3 is a cross- Fig. 4 is a side view showing the air circulation state of the decorative lighting mirror according to the present invention, Fig. 5 is a sectional view showing another embodiment of the decorative lighting mirror according to the present invention, and Fig. 6 is a view showing another embodiment of the decorative lighting mirror according to the present invention Fig. 7 is a perspective view showing another embodiment of the decorative lighting mirror according to the present invention. Fig.

Referring to FIGS. 1 and 2, the decorative lighting mirror of the present invention has a housing 100. The housing 100 includes a support plate 110 and a side plate 120. First, the support plate 110 is manufactured in the form of a plate having a predetermined thickness, and may be set up in a vertical direction.

The side plate 120 is protruded along the edge of the support plate 110. At this time, the side plate 120 is protruded by a predetermined distance in a direction intersecting the wide side surface of the support plate 110. Therefore, the shape of the housing 100 may be such that one side is open and the accommodation space S is formed therein.

The housing 100, that is, the decorative lighting mirror, may have a circular shape as shown in FIG. 1 or a square as shown in FIG. The frontal shape of the mirror is not limited thereto.

Referring to FIG. 2, an LED module 200 disposed in the accommodation space S is formed. The LED module 200 includes an LED 210 that emits light when receiving power from the outside, and an LED substrate 220 that supplies power to the LED 210. The LED substrate 220 is disposed adjacent to the inner side surface of the side plate 120 and the LED 210 is mounted on the LED substrate 220 to irradiate light emitted to the center of the housing 100 But it may be arranged to emit light in the open direction of the housing 100. [

Further, a reflection plate 300 for sealing the opened accommodation space S of the support plate 110 of the housing 100 is further provided. The reflection plate 300 may be fixed to the edge of the side plate 120 and then fixed by a separate fixing piece or the like. The reflection plate 300 may be made of transparent glass, acrylic, transparent plastic or the like, and a reflective coating layer 310 is coated on one surface of the reflection plate 300. An external object or a background may be reflected on the reflective coating layer 310 and recognized by the user on one side of the exposed reflective plate 300.

At this time, the reflection coating layer 310 applied to the reflection plate 300 may be applied to the reflection plate 300 except for a region that is arbitrarily set. Therefore, when the LED 210 installed inside the housing 100 emits light, the emitted light passes through the reflection plate 300 to the region where the reflection coating layer 310 is not applied.

Referring to FIG. 2, a controller 400 connected to the LED module 200 is installed on the reflection plate 300. The controller 400 corresponds to a switch capable of turning on / off the power supply of the LED 210 of the LED module 200. The controller 400 may be driven by various types of switches such as touch, insulation, and electric.

In addition, a controller 500 connected to the controller 400 is further provided in the housing 100. The control unit 500 controls the brightness, color, lighting, lighting time, etc. of the LED 210 according to various operations of the controller 400.

Referring to FIG. 3, an air inflow hole 121 passing through the side plate 120 is formed at one side of the side plate 120. Air outside the housing 100 can be introduced into the hermetically sealed housing 100 due to the air inflow hole 121.

4, a plurality of air discharge holes 301 are formed in the reflector 300 to communicate with the inside of the housing 100 and to discharge the air inside the housing 100 to the outside. At this time, the air discharge hole 301 is formed at a predetermined distance along the edge of the reflection plate 300, and the air discharge hole 301 is formed so as to reduce the amount of discharged air as the distance from the air discharge hole 121 increases. The area can be reduced.

3 and 4, an internal partition 600 is further provided between the side plate 120 and the LED module 200. The inner partition wall 600 has a purpose of partitioning between the side plate 120 and the LED module 200 and extends along the side plate 120. That is, the space between the inner partition wall 600 and the side plate 120 is communicated first with the air vent hole 301, and the space between the inner partition wall 600 and the LED module 300 And communicates with the inside of the housing 100 and the air inlet hole 121 in advance.

The heated air inside the housing moves along the space between the inner partition wall 600 and the side plate 120 when the LED 210 emits light and passes through the air discharge hole 301, 300). Therefore, it is possible to prevent moisture from being formed on the surface of the reflection plate 300, and even if moisture is formed on the surface of the reflection plate 300, an advantage of quick drying can be obtained.

3 and 4, the inner partition 600 includes a first inner partition wall 610, a second inner partition wall 620, a first guide partition wall 630, and a second guide partition wall 640.

The first inner partition wall 610 is disposed between the inner side surface of the side plate 120 and the LED module 200. That is, the first inner partition wall 610 includes a first 1-1 circular path 610-1 adjacent to the side plate 120 and a second 1-2 circular path 610-1 adjacent to the LED module 200, ).

The second inner partition wall 620 is symmetrical about the first inner partition wall 610 and the air inflow hole 121 in the vertical direction with reference to FIG. That is, the second inner partition wall 620 includes a second-1 circular path 620-1 adjacent to the side plate 120 and a second 2-2 circular path 620-1 adjacent to the LED module 200, ).

The first guide partition 630 extends from one end of the first inner partition wall 610 and has an end seated at an edge of the air inlet hole 121 so that the air introduced into the air inlet hole 121 flows into the housing 100 To the inside thereof.

The second guide partition 630 is symmetrical about the first guide partition 630 and the air inlet hole 121 and extends from one end of the second inner partition wall 620, And is positioned at the edge of the hole 121 to guide the air introduced into the air inlet hole 121.

At this time, the other end of the first inner partition wall 610 and the other end of the second inner partition wall 620 are spaced apart from each other by a predetermined distance, and the first 1-1 second circulation passage 610-1, And a branch hole 650 for connecting the second-2 ring-shaped ring-shaped ring 610-2, the second-2 ring-shaped ring-shaped ring-shaped ring-shaped ring 620-1, Therefore, the air introduced into the air inlet hole 121 can be circulated in the housing 100 and discharged to the air outlet hole 301.

Will be described in more detail with reference to FIGS. 3 and 4. FIG. When the LED 210 emits light, the LED substrate 220 is heated due to the light emitted from the LED 210, and at the same time, the air inside the housing 100 is heated. At this time, the air located in the first-second circulation path 610-2 and the second-second circulation path 620-2 between the LED module 200 and the first and second inner partition walls 610 and 620 is rapidly heated, 2 circulation path 610-2, and the 2-2th circulation path 620-2 to the upper side of the housing 100. Thereafter, the heated air passes through the branch hole 650 and moves to the first circulation path 610-1 or the second-1 circulation path 620-1.

At this time, the atmospheric pressure of the accommodation space S inside the housing 100 is lowered so that the air outside the housing 100 flows into the air inlet hole 121. The incoming air flows through the first and second circulation paths 610-2, And then passes through the 2-2th circulation path 620-2.

Due to the convection of air, the heated air moves along the first circulation path 610-1 or the second-1 circulation path 620-1, passes through the air discharge hole 301, Lt; / RTI > At this time, since the area of the air discharge hole 301 is sequentially widened in accordance with the moving direction of the air, uniformly heated air can be discharged through the plurality of air discharge holes 301. Therefore, since the heated air is in contact with the surface of the reflection plate 300, it is possible to prevent dew or moisture from being formed on the surface of the reflection plate 300.

In addition, air circulation inside the housing 100 can be smoothly performed to improve the cooling efficiency of the LED module 200, thereby prolonging the life of the LED 210.

Referring to FIG. 5, a rotating rotor 651 having a plurality of blades protruding from the branch hole 650 may be rotatably installed. The rotation rotor 651 rotates according to the flow of the moving air to provide a driving force to the air moving to the 1-1 and 6-1 circulation paths 610-1 and 620-1. In addition, a separate perfume may be further provided in the air inlet hole 121 so that the air is discharged to the air outlet hole 301 by circulation of the air and the aroma is spread in the indoor space.

Referring to FIG. 5, a reverse flow preventing rib 700 is formed in the 1-1 and 6-1 circulation paths 610-1 and 620-2 at a predetermined interval. The backflow prevention ribs 700 are protruded to have a predetermined radius of curvature and spaced apart from each other along the air movement directions of the 1-1 and 6-1 second circulation paths 610-1 and 620-2. At this time, it is preferable that the direction of the end of the backflow preventing rib 700 is directed to the opposite direction of the moving air. Therefore, the air that flows into the 1-1 circulation path 610-1 and the 2-1th circulation path 620-2 flows backward through the air discharge hole 301 by the backflow prevention ribs 700 .

Another embodiment of the present invention will be described in detail with reference to FIG.

The decorative illuminating mirror of the present invention includes a support plate 110 having a predetermined thickness and a side plate 120 protruding in a direction intersecting the side of the support plate 110 along the edge of the support plate 110, (100). At this time, a part of one surface of the support plate 110 is coated with a first reflective coating layer 111 having a predetermined diameter and reflecting an external object.

The LED module 200 is provided at the edge of the first reflective coating layer 111. The LED module 200 may be formed in a ring shape that forms a closed-loop along the edge of the first reflective coating layer 111. The LED module 200 includes an LED 210 that emits light by being supplied with power from the outside so as to irradiate light emitted at the center of the support plate 110 and an LED 210 having a width equal to the protruding length of the side plate 120. [ (220).

The reflector 300 is further secured to the side plate 120 by being seated on the edge of the side plate 120 to seal the opened accommodation space S of the housing 100. The reflection plate 300 may be made of transparent glass, acrylic, or the like. A second reflective coating layer 310 is applied to the inner surface of the reflective plate 300. The second reflective coating layer 310 is formed on the inner surface of the reflective plate 300 except for the area facing the first reflective coating layer 111. [ As shown in Fig. Therefore, the first reflective coating layer 111 can be identified as a region of the reflective plate 300 to which the second reflective coating layer 310 is not applied. That is, when the reflection plate 300 is viewed from the front, external objects reflected by the first reflection coating layer 111 can be visually confirmed.

The controller 400 may further include a controller 400 connected to the LED module 200 to turn on / off the LED 210. When the LED 210 is emitted through the controller 400, the light emitted from the LED 210 may be reflected or diffused repeatedly between the first reflective coating layer 111 and the inner surface of the reflective plate 300. The reflected light passes through the reflection plate 300 to which the second reflective coating layer 310 is not applied and is irradiated to the outside of the housing 100.

That is, since the direct light of the LED 210 is repeatedly reflected, it is not directly irradiated to the user, thereby preventing glare. In addition, the LED 210 can be used in a dark place and provide a soft lighting effect, There is an advantage.

Further, it is possible to prevent moisture from being formed on the surface of the mirror as well as the illumination function through the heat generated during the heat generation of the LED module 200, thereby providing an additional advantage that the lifetime of the LED module 200 can be extended to provide.

100: housing 200: LED module
300: reflector 400: controller
500: control unit 600: inner partition wall
610: first inner partition wall 620: second inner partition wall
630: first guide rib 640: second guide rib
650: branch hole 700: reverse flow preventing rib

Claims (6)

A supporting plate 110 having a predetermined thickness and a receiving space S formed at an edge of the supporting plate 110 so as to protrude at predetermined intervals in a direction intersecting the side surface of the supporting plate 110 (100) comprising a side plate (120) to which the side plate (120) is attached;
An LED 210 disposed in the accommodation space S and adjacent to an inner side surface of the side plate 120 to emit light emitted from the center of the support plate 110 by being supplied with power from the outside, LED module 200;
A reflection plate 300 which is fixed to an edge of the side plate 120 to seal the accommodation space S and to which a reflective coating layer 310 is applied so as to reflect an external object on one exposed side;
A controller 400 connected to the LED module 200 to control light emission of the LED 210;
And a controller 500 connected to the controller 400 and controlling brightness, color, and light emission of the LED 210 according to an operation of the controller 400,
The reflective coating layer 310 is applied except for a region that is arbitrarily set so that the light of the LED 210 emitted from the inside of the housing 100 passes through the outside,
An air inlet hole 121 through which external air flows into the housing 100 is formed at one side of the side plate 120 and an air exhaust hole 121 communicating with the interior of the housing 100 is formed in the reflector 300. [ (301) are spaced apart from each other by a predetermined distance,
The heated air inside the housing 100 when the LED 210 emits light is in contact with the surface of the reflector 300 after the air passes through the air outlet hole 301, And an inner partition wall (600) for partitioning between the side plate (120) and the LED module (200) so as to prevent a phenomenon that the LED module (200) is formed. delete The method according to claim 1,
The inner partition wall 600 is formed between the inner side surface of the side plate 120 and the LED module 200 and includes a first circulation path 610-1 adjacent to the side plate 120, A first inner partition wall 610 for partitioning the first to-2nd circulation path 610-2 adjacent to the first inner partition wall 610-2;
A second 2-1 circulation path 620-1 adjacent to the side plate 120 and a second 2-2 circulation path 620-2 adjacent to the LED module 200 are arranged symmetrically with the first inner partition wall 610, A second inner partition wall 620 partitioning the second inner partition wall 620;
A first guide partition wall 630 extending from one end of the first inner partition wall 610 and guiding air introduced into the air inlet hole 121;
And a second guide partition wall 640 which is symmetrical with the first guide partition 630 and extends from one end of the second inner partition wall 620 to guide air introduced into the air inlet hole 121 Wherein the mirror is a mirror. The method of claim 3,
The first to third circulation paths 620-1 and 620-2 are connected to each other so as to be communicated with each other through the first 1-1 circulation path 610-1, the 1-2th circulation path 610-2, the 2-1th circulation path 620-1, A branch hole 650 is formed between the other end of the inner partition 610 and the other end of the second inner partition 620,
When the LED 210 emits light and the air existing in the accommodation space S is heated, the heated air is circulated along the first and second circulation roads 610-2 and 620-2, Is passed through the hole (650), passes through the 1-1 circulation path (610-1) and the 2-1th circulation path (620-2), and is discharged to the air discharge hole (301). The method of claim 3,
The first 1-1 circulation path 610-1 and the second 2-1 circulation path 620-2 are provided with the first 1-1 circulation path 610-1 to prevent the air discharged to the air discharge hole 301 from flowing backward. And a reverse flow preventing rib (700) protruding from the second circulation path (620-2) with a predetermined radius of curvature in the direction of air moving through the second circulation path (620-2). delete

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