KR20070017684A - A combined picture frame and mirror - Google Patents

Abstract

According to the present invention, the half mirror 160 is coupled to the front side of the housing 100, and the image film 180 is mounted between the half mirror 160 and the housing 100, whereby the image film 180 is formed. The present invention relates to a frame having a mirror functioning as a frame or a mirror according to whether the backlight unit 130 on the rear side is turned on. An infrared sensor which detects a person's approach and generates a detection signal on one side of the housing 100. 105 is formed, and the backlight unit 130 controls the lighting of the backlight unit 130 by a detection signal transmitted from the infrared sensor 105, but when a person approaches the frame, the housing ( Blinking or lighting the backlight unit 130 in the 100 to be used as a mirror or a picture frame, and when the person is far away, the backlight for lighting or blinking the backlight unit 130 to be used as a picture frame or a mirror. The light lighting circuit 110 is coupled, and the ground copper plate 150 is coupled to the rear surface of the half mirror 160, and the ground copper plate 150 is electrically connected to the ground terminal 120 of the backlight lighting circuit 110. It relates to a picture frame having a mirror function characterized in that connected to.

Half mirror, picture frame, mirror, infrared sensor

Description

A combined picture frame and mirror}

1 is an exploded perspective schematic view of a frame having a mirror function of the present invention.

2 is a partially exploded perspective schematic view of a frame having a mirror function of the present invention.

Figure 3 is a perspective schematic diagram showing a combined state of the picture frame with a mirror function of the present invention.

Figure 4 is an enlarged cross-sectional view of the main portion of the frame with a mirror function of the present invention.

5 is a perspective schematic view of a frame having a conventional mirror function.

<Description of Major Symbols in Drawing>

100 housing 102 recessed part

104: light emitting unit 105: infrared sensor

106: light receiver 108: through hole

110: backlight unit lighting circuit 112: power supply terminal

120: ground terminal 130: backlight unit

140: "┗┛" type sliding spacer 142: sliding groove

144: infrared transmission window 146: through hole

150: ground copper 160: half mirror

162: through hole 164: bolt

168: nut 170: sliding image frame

172: Case 174: Square Through Hole

176: jaw 178: fixed frame

180: image film

The present invention relates to a frame having a mirror function. More particularly, the present invention relates to a picture frame having a mirror function for selectively performing a mirror function and a picture frame function for displaying an image such as a photo therein by emitting a light source through a backlight unit based on an input signal from a sensor.

Conventional picture frames are mainly in the form of simply inserting a picture. Such a conventional picture frame has only a simple picture frame function, and thus has only a decorative effect and no functional aspect.

On the other hand, the conventional mirror combined picture frame which gave the functional surface is implemented. Such a mirror-shaped frame has a housing, an infrared sensor is formed on one side of the housing, and a lighting control circuit for turning on / off the backlight unit is formed in the housing according to a detection signal of the infrared sensor. The half mirror is formed by combining. Here, the half mirror is coated with a metal material such as aluminum, titanium, nickel, chromium for mirror deposition on the rear surface. Therefore, when the infrared sensor is located at the rear part of the half mirror, the infrared ray transmittance is only about 10% by the metal material coated on the rear part of the half mirror, and infrared transmission is virtually impossible at the rear part of the half mirror. Therefore, the infrared sensor could not be located on the rear side of the half mirror.

When power is applied to the backlight unit, a high voltage constant voltage is generated on the rear surface of the half mirror by the metal material coated on the rear surface of the half mirror, so that the transmittance of infrared rays is significantly reduced to 10% or less. Therefore, the conventional mirror frame does not have an infrared sensor installed on the rear half mirror, and as shown in FIG. 5, the frame 10 having the conventional mirror function is the half mirror 30 coupled to the housing 20. The infrared sensor 40 had to be placed outside of the installation. That is, since the infrared sensor 40 detects a person's approach only when the infrared sensor 40 is exposed to the outside, there is a problem that the infrared sensor 40 must be separately formed outside the half mirror 30.

On the other hand, when power is applied to the backlight unit, a high voltage constant voltage is generated on the metal coating on the rear surface of the half mirror. The high voltage constant voltage generated here causes a problem of damage to the control circuit board, and has a problem of significantly shortening the life of the mirror-compatible frame that can be used for a long time.

Meanwhile, the conventional mirror-type photo frame is used by fixing the image film between the backlight unit and the half mirror inside the housing. To replace the image film therein, the assembled housing must be disassembled to replace the image between the backlight unit and the half mirror. There was a troublesome problem.

The present invention solves the problem that infrared rays do not penetrate the half mirror due to the constant voltage applied to the rear surface of the half mirror, thereby making it possible to install an infrared sensor on the rear surface of the half mirror, thereby eliminating the conventional problem of covering the infrared sensor outside the mirror. Its purpose is to solve it.

On the other hand, the present invention by combining the ground copper plate on the back of the half mirror to remove the high voltage constant voltage generated in the metal material coated on the back of the half mirror when power is applied to the backlight unit, the transmittance of the infrared sensor is significantly increased, The purpose is to provide a frame having a mirror function that can be used for a long time by preventing damage to the control circuit board due to the constant voltage.

The present invention provides a frame having a mirror function formed of a sliding spacer formed with a sliding groove between the backlight unit and the half mirror inside the housing so that an image such as a picture can be easily replaced by sliding engagement and release from the outside. Its purpose is to.

According to the present invention, the half mirror 160 is coupled to the front side of the housing 100, and the image film 180 is mounted between the half mirror 160 and the housing 100, whereby the image film 180 is formed. The present invention relates to a frame having a mirror functioning as a frame or a mirror according to whether the backlight unit 130 on the rear side is turned on. An infrared sensor which detects a person's approach and generates a detection signal on one side of the housing 100. 105 is formed, and the backlight unit 130 controls the lighting of the backlight unit 130 by a detection signal transmitted from the infrared sensor 105, but when a person approaches the frame, the housing ( Blinking or lighting the backlight unit 130 in the 100 to be used as a mirror or a picture frame, and when the person is far away, the backlight for lighting or blinking the backlight unit 130 to be used as a picture frame or a mirror. The light lighting circuit 110 is coupled, and the ground copper plate 150 is coupled to the rear surface of the half mirror 160, and the ground copper plate 150 is electrically connected to the ground terminal 120 of the backlight lighting circuit 110. It relates to a picture frame having a mirror function characterized in that connected to.

Here, a sliding groove 142 is formed on the front surface of the housing 100 to which the backlight unit 130 is coupled along the inner edge and a plurality of infrared transmission windows 144 are formed at predetermined intervals. Spacer 140 is coupled, the half mirror 160 is coupled to the front of the "┗┛" type sliding spacer 140, the sliding groove 142 of the "┗┛" type sliding spacer 140 Preferably, the sliding image frame 170 is formed to be coupled to the sliding.

On the other hand, power is applied to the backlight unit 130 by the ground copper plate 150 to remove the high voltage constant voltage generated from the metal-coated rear surface of the half mirror 160.

On the other hand, the sliding image frame 170 has a rectangular through-hole 174 is formed in the inside of the case 172 formed in a rectangular shape so that light passes through when the backlight unit 130 emits light, An anchor jaw 176 is formed to enclose an image 180 such as a photo by the periphery of the through hole 174, and a fixing frame 178 for fixing an image 180 such as a photo enclosed by the encasement 176. ) Is formed to facilitate replacement of the image film 180.

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

As shown in Figure 1, the housing 100 has a plurality of through-holes 108 are formed in the outer peripheral side in the shape of a square, the concave portion 102 is formed inward. Here, the concave portion 102 is provided with components such as a circuit board and the infrared sensor 105 is formed on one side of the housing 100.

The infrared sensor 105 is formed of the light emitting unit 104 and the light receiving unit 106. The light emitting unit 104 of the infrared sensor 105 emits infrared light so that a light source reflected by a person as it approaches is easily detected by the light receiving unit 106. Inclined at a predetermined angle.

The backlight unit lighting circuit 110 has a power terminal 112 is formed to apply power to each portion, the ground terminal 120 of the ground copper plate 150 to be described later is formed, the recessed portion of the housing 100 Is implied at 102. Here, the backlight unit lighting circuit 110 is connected to the light emitting unit 104 and the light receiving unit 106 of the infrared sensor 105 and receives the detection signals of the light emitting unit 104 and the light receiving unit 106 will be described later according to the detection signal The lighting and flashing of the backlight unit 130 are controlled.

The backlight unit 130 is formed in a rectangular shape so as to emit a uniform light source over the entire surface. Here, the backlight unit 130 is connected to the backlight unit lighting circuit 110 so that lighting and blinking are controlled by the backlight unit lighting circuit 110 according to the detection signal of the infrared sensor 105.

Sliding spacer 140 of the "┗┛" type is formed with a plurality of through holes 146, the sliding groove 142 is formed along the inner edge and a plurality of infrared transmission window 144 is formed on one side. Here, the “┗┛” shaped sliding spacer 140 is coupled to the housing 100 through the through hole 146 by bolts and nuts, thereby fixing the outer edge of the backlight unit 130, and an elliptical shape formed at one side. The infrared sensor 105 is inserted into and formed at a plurality of infrared transmission windows 144 at a predetermined distance to adjust the infrared sensor 105 at a predetermined angle through the front surface of the ellipse of the infrared transmission window 144 to detect the infrared rays. The rate is formed to be maximum.

The ground copper plate 150 is coupled to one side of the “┗┛” type sliding spacer 140 and coupled to the ground terminal 120 formed in the backlight unit lighting circuit 110. Here, when the power is applied to the backlight unit 130, the ground copper plate 150 receives a constant voltage of a high voltage generated by a specially coated metal on the rear surface of the half mirror 160 through the ground copper plate 150. It is removed through the ground terminal 120 formed at 110.

The half mirror 160 has a plurality of through holes 162 formed at one side thereof. Here, when the backlight unit 130 is turned on, the half mirror 160 is seen to be transmitted through the inside, like transparent glass. When the backlight unit 130 is turned on, the half mirror 160 is formed to be opaque to perform a mirror function. It is coupled to the front of the sliding spacer 140.

In the sliding image frame 170, the case 172 is formed in a rectangle, and the power is supplied to the backlight unit 130 from the backlight unit lighting circuit 110 by the sensing signal detected by the infrared sensor 105 in the ON state. Thus, when the backlight unit 130 is turned on, a rectangular through hole 174 is formed to pass through the light source. Here, a settling jaw 176 for enclosing the image film 180 is formed on the outer periphery of the rectangular through hole 174, and a fixing frame 178 for fixing the image film 180 settled on the settling jaw 176. Is formed. That is, when the image film 180 is replaced, the frame is formed to be easily replaced by slidingly coupled to the sliding groove 142 of the “┗┛” -type sliding spacer 140, thereby easily displaying an image 180 such as a photograph. It can be replaced.

Looking at the assembly and operation of the frame having a mirror function of such a configuration as follows. As shown in FIGS. 1 to 3, the power supply terminal 112 and the ground part are connected to the recess 102 of the housing 100 having the infrared sensor 105 formed of the light emitting part 104 and the light receiving part 106. A backlight unit lighting circuit 110 in which the 120 is formed is formed so that the infrared sensor 105 and the backlight unit 130 are connected to the backlight unit lighting circuit 110.

Herein, the light receiving unit 106 detects the infrared rays reflected by a person near the infrared rays generated by the light emitting unit 104 and transmits a detection signal to the backlight unit lighting circuit 110 so as to have an optimal sensing distance. Placed at intervals, as shown in Figure 4 is disposed inclined at a predetermined angle inside the housing 100. That is, the infrared sensor 105 is disposed in the housing 100 at an optimal distance and angle to detect the infrared sensor 105 to maximize the detection rate.

Thus, the backlight unit 130 is placed inside the housing 100 in which the infrared sensor 105 formed by the light emitting unit 104 and the light receiving unit 106 and the backlight unit lighting circuit 110 are installed. The sliding spacer 140 is fitted to the housing 100.

When the backlight unit 130 is turned on to the front side of the 스페이서 ″ type sliding spacer 140 fitted to the housing 100, the image film 180 is transparent to be shown therein, and in the blinking state. The half mirror 160, which is opaque and can perform the function of the mirror, is coupled, where the coupling of the half mirror 160 to the housing 100 is through-hole 162 of the half mirror 160 by the bolt 164. It is preferable to be firmly coupled to the nut 168 through the through hole 146 of the sliding spacer 140 and the through hole 108 of the housing 100.

As described above, the sliding image frame 170 is slidably coupled to the sliding groove 142 formed in the ┗┛ " type sliding spacer 140 of the frame having the combined mirror function. In this case, the sliding image frame 170 The image film 180 is placed on the settling 176 formed at the outer periphery of the rectangular through hole 174 of the case 172 to fit the fixing frame 178 to the settling 176 to fix the image film 180. In other words, in order to replace the image film 180 in the picture frame having a mirror function, without sliding the entire frame to replace the replacement without sliding the sliding groove 142 formed in the "스페이서" type sliding spacer 140 It is possible to easily replace the image film 180 by separating only the sliding image frame 170 from the frame.

The frame having the mirror function assembled through such an assembly process normally performs the function of the frame to display the image film 180 therein while the backlight unit 130 is kept lit. When approaching, the infrared sensor 105 detects an approaching person and transmits a detection signal to the backlight unit lighting circuit 110. The backlight unit lighting circuit 110 receiving the detection signal blinks the backlight unit 130 by the detection signal, thereby performing a mirror function.

In addition, lighting and blinking of the backlight unit 130 of the frame having a mirror function may be used by reversely turning on and blinking the backlight unit 130 described above. That is, normally, the backlight unit 130 maintains the flashing state to perform a mirror function by the half mirror 160, but when a person approaches, the infrared sensor 105 detects a person near and detects a detection signal. By transmitting to the backlight unit lighting circuit 110 to light the backlight unit 130 by the detection signal, it performs a function of a frame so that the image film 180 is not visible inside.

On the other hand, when the backlight unit 130 is maintained in a lighting state, a high voltage constant voltage is generated by a metal or the like specially coated on the rear surface of the backlight unit 130. The high voltage constant voltage generated is a ground terminal formed at the backlight unit lighting circuit with the high voltage constant voltage in a state in which the ground copper plate 150 formed at one side of the ″ ″ type sliding spacer 140 is grounded at the rear surface of the half mirror 160. By removing through 120, the transmittance of the infrared sensor 105 located at the rear portion of the half mirror is maintained at 40% to 50% so that it can be installed at the rear side of the half mirror 160 without exposing the infrared sensor to the outside. do.

Therefore, when the transmission of the infrared sensor exceeds 40% to 50% and the backlight unit 130 operates in a lit state, the light source of the backlight unit 130 emits light evenly over the front surface and emits light. The half mirror 160 is made transparent so that the image film 180 slidingly coupled to the inside of the housing 100 can be confirmed. In addition, by removing the high voltage constant voltage generated on the rear surface of the backlight unit 130 by the ground copper plate 150, it is possible to prevent damage to internal components such as the control circuit board due to the high voltage constant voltage.

The embodiments of the present invention described above are examples of one of the embodiments of the present invention, and the present invention is not limited thereto, and the present invention includes equivalents and equivalents thereof.

The present invention solves the problem that infrared rays do not penetrate the half mirror due to the constant voltage applied to the rear surface of the half mirror, thereby making it possible to install an infrared sensor on the rear surface of the half mirror, thereby eliminating the conventional problem of covering the infrared sensor outside the mirror. It is effective to solve.

On the other hand, the present invention by combining the ground copper plate on the back of the half mirror to remove the high voltage constant voltage generated in the metal material coated on the back of the half mirror when power is applied to the backlight unit, the transmittance of the infrared sensor is significantly increased, It is effective to provide a frame having a mirror function that can be used for a long time by preventing damage to the control circuit board due to the constant voltage.

The present invention provides a frame having a mirror function formed of a sliding spacer formed with a sliding groove between the backlight unit and the half mirror inside the housing so that an image such as a picture can be easily replaced by sliding engagement and release from the outside. It is effective.

Claims (4)

The half mirror 160 is coupled to the front side of the housing 100, and the image film 180 is mounted between the half mirror 160 and the housing 100, whereby the rear side of the image film 180 is located. In the picture frame having a mirror function that functions as a picture frame or a mirror depending on whether the backlight unit 130 is turned on, An infrared sensor 105 is formed at one side of the housing 100 to detect a person's approach and generate a detection signal. The backlight unit 130 controls the lighting of the backlight unit 130 by a detection signal transmitted from the infrared sensor 105, but when a person approaches the frame, the backlight unit 130 in the housing 100. ) Flashes or lights to be used as a mirror or a picture frame, and when a person is far away, the backlight lighting circuit 110 for lighting or blinking the backlight unit 130 to be used as a picture frame or a mirror is combined. The ground copper plate 150 is coupled to the rear surface of the half mirror 160, The ground copper plate 150 is electrically connected to the ground terminal 120 of the backlight lighting circuit 110 Picture frame with mirror function. The method of claim 1, Sliding groove 142 of the sliding groove 142 is formed on the front surface of the housing 100 to which the backlight unit 130 is coupled and the plurality of infrared transmission windows 144 are formed at a predetermined interval ( 140) are combined, Half mirror 160 is coupled to the front of the "┗┛" type sliding spacer 140, Sliding image frame 170 is formed to be slidingly coupled to the sliding groove 142 of the "┗┛" type sliding spacer 140, characterized in that Picture frame with mirror function. The method of claim 1, Power is applied to the backlight unit 130 by the ground copper plate 150 to remove the high voltage constant voltage generated from the metal-coated rear surface of the half mirror 160. Picture frame with mirror function. The method of claim 2, The sliding image frame 170 has a rectangular through-hole 174 is formed inside the case 172 formed in a square so that light passes through the backlight unit 130 to emit light, A settling jaw 176 is formed to settle the image 180 such as a picture by the outer edge of the rectangular through hole 174, It characterized in that the fixing frame 178 for fixing the image 180, such as a picture placed on the settled jaw 176 is formed Picture frame with mirror function.

Images