KR0158321B1 - Structure of infrared receiving unit of remote controller - Google Patents

Abstract

The present invention improves the structure of the light receiving guide 24 for receiving the infrared light emitted from the remote controller and guides it to the light receiving sensor 12 to widen the angle of detection of infrared rays, blocking the loss of the received infrared light as much as possible And an infrared receiver of a remote control device for condensing the light with a light receiving sensor unit to achieve a reliable operation. Referring to the structure of the present invention, a light receiving sensor for recognizing infrared rays received at one side of the substrate 11 and a substrate are provided. It is provided on the other side of the lamp 13 to indicate the operating state of the product, and the coupling pin 21 is coupled to the substrate on both sides of the light receiving sensor and the upper part of the lamp and at the same time protrudes outward And a cover 20 having a light receiving guide 24 for guiding infrared light to a light receiving sensor and a light emitting guide 26 for releasing light from the lamp to the outside. The end portion of the light emitting guide is formed by the curved portion 24a, and the cutout holes 23 are formed at both sides of the connection portion between the light emitting guide and the cover to prevent the infrared rays from being received by the cover and being lost. The light blocking plate 30 to prevent interference of light is interposed.

Description

Structure of Infrared Receiver of Remote Controller

1 is an exploded perspective view showing the structure of a receiver according to the prior art.

2 is a front sectional view of a cover according to the prior art.

Figure 3 is an exploded perspective view showing the structure of the receiving unit according to the present invention.

Figure 4 is a front sectional view of the cover according to the present invention.

5 is a plan view showing the main portion of FIG.

6 is a perspective view of the assembled state of the present invention.

7 is a perspective view showing the structure of a light shielding film of the lamp unit applied to the present invention.

8A and 8B are plan views illustrating a light shielding film installation structure of a lamp unit according to the present invention.

* Explanation of symbols for main parts of the drawings

11 substrate 12 light receiving sensor

13: lamp 20: cover

21: coupling pin 23: cutting hole

24: light receiving guide 24a: curved portion

24b: reflecting film 26: light emitting guide

30: shading plate 30a: plate

30b: middle plate

The present invention relates to an infrared receiver of a remote control device, and in particular, to improve the structure of the light receiving guide unit for receiving the infrared light emitted from the remote controller to guide it to the light receiving sensor unit to increase the detection angle of the infrared light, the received infrared light This invention relates to an infrared receiver of a remote control device that can block the loss of the light as much as possible and condense it to the light receiving sensor unit to achieve reliable operation.

In general, in the electronic product operation, the user seeks convenience so that the user can directly access the product and operate it at a long distance through the far-end adjusting device using infrared rays without operating the operation switch installed therein.

The above-mentioned distance adjusting device includes a remote control for transmitting different frequencies according to the control purpose, and a receiving unit for receiving the frequency transmitted from the remote control and recognizing it as each frequency.

1 is an exploded perspective view showing a structure of a receiver according to the related art, in which a light receiving sensor 12 is connected to one side of a substrate 11 and a lamp 13 for displaying an operating state is installed on one side for each color. The upper part of the cover 20 is semi-transparent to cover the substrate 11 by a coupling pin 21 protruding downward for the beauty of the appearance of the product.

In addition, the cover 20 includes a light receiving guide 14 protruding to effectively transmit infrared rays transmitted to the light receiving sensor 12, and a light emitting guide 16 protruding to emit light emitted from the lamp 13 to the outside. Is installed.

The light receiving guide 14 receives the infrared rays transmitted and is collected by a curved surface formed convexly at the bottom by being reflected in a zig-zag from the inside as shown in FIG. 2 and guided to the light receiving sensor 12. The guide 16 protrudes to the upper and lower portions of the cover 20, and a lower end thereof is formed to be close to the lamp 13 to reflect the light emitted from the lamp 13 to the outside as opposed to the light receiving guide 14.

However, in the conventional structure as described above, the light receiving sensor 12 does not recognize this if the supply amount of infrared rays emitted from the remote controller is not appropriate, and cannot expect a desired remote control. This may be caused by a lack of this or the location of the infrared radiation being too square.

That is, in the latter case, the end portion of the conventional light emitting guide 16 has a planar structure, and the light emitting guide 16 which receives light when the infrared light emitted from the remote controller forms a direction substantially perpendicular to the light emitting guide 16. Infrared rays contacting the end contact surface of the panel may not come into contact with each other or only a small amount of contact.

This phenomenon becomes apparent as the square gets larger.

Therefore, since the infrared ray transmitted from the blind spot is not properly received, the angle of use of the remote controller is not only narrowed, and the light emitting guide 16 is integral with the cover 20 and has the same material, so that the infrared rays passed through the cover of the same medium are used. It is scattered much by (20) and is lost. Therefore, the amount of infrared light perceived by the light receiver is insufficient, so remote control cannot be performed properly.

In addition, the light emitted by each lamp 13 is not only emitted by the corresponding light emitting guide 16 but is emitted in all directions. Therefore, the light is also emitted to other light emitting guides 16 to cause interference, so when one lamp 13 is turned on, the light is not only to the corresponding light emitting guides 16 but also to the light emitting guides 16 on its side. When the lamp 13 is turned on at the same time according to the operating situation, it is difficult for the user to recognize the operating state of the product quickly. Since the color of the light emitted through each of the colors of the lamp 13, that is, the middle color, that is, the mixed color appears, the user has a difficult end to distinguish the current operating state.

Accordingly, the present invention has been made to solve the above-described conventional end, the object of which is to improve the structure of the light receiving guide portion to broaden the recognition range of the transmitted infrared light receiving angle, and to prevent the loss of infrared rays supplied to the light receiving sensor to the maximum. To improve the dignity control system.

Another object of the present invention is to allow the user to easily recognize the current state of product operation by allowing the light emitted from the lamp through the light emitting guide to emit only the corresponding light emitting guide.

Means of the present invention for achieving the above object is provided with a light receiving sensor that recognizes the infrared light received on one side of the substrate, and a lamp installed on the other side of the substrate to indicate the operating state of the product, coupled to the substrate on both sides A cover having a light receiving guide for guiding the infrared light to the light receiving sensor and being projected to the outside at the same time as the upper surface of the light receiving sensor and the lamp is provided with a coupling pin, In the receiving unit, the end portion of the light emitting guide is formed as a rounded curved portion, characterized in that the infrared light received by the cutout holes on both sides of the connection portion between the light emitting guide and the cover is not dispersed to the cover.

In addition, the present invention is a curvature of the curved portion is made by the radius of the projection height of the light receiving guide.

In addition, a light shielding plate for preventing interference between the lamps between the respective lamps is characterized in that it is provided.

In installing the light shielding plate in the lamp, when the number of lamps is two, the middle plate portion formed at right angles is interposed between the two lamps, and when the number of lamps is three, the drawing light shielding plate is obliquely positioned. It is installed so as to be located within the angle between the middle plate protruding at right angles and the one side plate forming a right angle.

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

Figure 3 is an exploded perspective view showing the structure of the light receiving sensor according to the present invention, Figure 4 is a front sectional view of the cover according to the present invention, Figure 5 is a plan view showing the main portion of Figure 4, Figure 6 is a It is a perspective view of a state, FIG. 7: is a perspective view which shows the structure of the light shielding film of the lamp part applied to this invention, and FIG. 8A, 8B is a plan view which shows the light shielding film installation structure of the lamp part applied to this invention.

3 and 6, a light receiving sensor for detecting infrared rays is installed on one side of the upper surface of the substrate, and lamps 13 for displaying the operating state of the product are installed on the other side for each color. The cover 20 is covered by the top.

As shown in Figure 4, the side of the cover 20, the engaging pin 21 is formed in the end of the engaging projection 21 is formed to protrude downward to the coupling hole 17 of the substrate 11 is inserted and fixed .

The cover 20 is provided with a light receiving guide 24 protruding in a cylindrical shape at the position where the light receiving sensor 12 is located, the end of the light receiving guide 24 is a radius (R) protruding height (L) Consists of a convex curved portion (24a), the root portion of the light receiving guide 24 also forms a convex curved downward to focus the light to the light receiving sensor (12).

Since light passes through the same medium and is reflected at its boundary when the medium is different, the cutout hole 23 is formed in the cover 20 of both sides of the light receiving guide 24 as shown in FIG. do. In this case, the light receiving guide 24 is supported by a stay that separates both cutout holes 23.

In addition, the reflection film 24b is covered around the light reception guide 24 to prevent the infrared light received from the curved portion 24a from being lost to the outside of the light reception guide when reflected by the zigzag. Silver Al film (aluminum foil) is preferable.

In addition, a light emitting guide 26 is formed on the cover 20 of the portion where the lamp 13 is located so as to correspond to each lamp 13, and the light emitting guide 26 protrudes to the upper surface of the cover 20. At the same time it is formed and protrudes to the lower surface, the end is installed in close proximity to the lamp 13 so that it is easy to emit the light of the lamp 13 to the outside.

In addition, as shown in FIG. 7, a light shield plate 30 is disposed between the lamps 13 so that the light does not interfere with other light emitting guides 26 when the light is emitted. A plate 30a having a space height of the 11 and the cover 20, the transverse direction of the plate 30a is formed, and a middle plate 30b protruding at right angles therebetween is formed to have a T shape.

In installing the T-shaped light shielding plate 30, in the case where the number of the lamps 13 is two, as shown in FIG. 8A, the middle of the light shielding plate 30 between the lamps 13 is located at right angles. The plate 30b is installed to be interposed, and when the number of lamps 13 is three, as shown in FIG. 8B, the light blocking plate 30 is obliquely positioned and the intermediate plate 30b protrudes at right angles. It is installed to be located within the angle between the one side plate (30a) forming a right angle.

Looking at the operation and effects of the present invention by the above structure as follows.

First, when the user adjusts a remote control not shown in the drawing to emit infrared light, the infrared light is transmitted to the end of the light receiving guide 24 protruding from the cover 20, and the transmitted infrared light is received inside the light receiving guide 24. Reflected by the zigzag and guided to the bottom, the lower end of the light receiving guide 24 is curved so that it is collected while passing through the light receiving sensor 12 installed in the substrate (11).

In addition, when the user's position is operated in the square of the product, the emitted infrared light passes through the end of the light receiving guide 24, and when the end thereof is flat as in the prior art, there is no surface contacting it, but the light is not received. Since the curved portion 24a is formed at the end of the light receiving guide 24 of the present invention, the light receiving area is secured by the height of the protruding curved portion 24a. A sufficient amount of light that can be recognized can be obtained.

In addition, infrared rays passing through the light receiving guide 24 form cutout holes 23 on both sides of the cover 20 connected to the light receiving guide 24 to separate the cover 20 and the light receiving guide 24. Therefore, as shown in the related art, the cover 20 having the same medium is dispersed in itself, thereby preventing the loss of infrared rays, and the reflective film 24b made of a material that reflects light well to the outside of the light receiving guide 24 is covered. Infrared rays, which are reflected while being reflected in the light receiving guide 24 through the curved portion 24a in a zigzag, are not completely reflected when reflected from the surface of the light receiving guide 24, and some are lost to the outside. Since the reflecting film 24b is reflected back to the light receiving guide 24, the infrared rays once introduced into the light receiving guide 24 are completely blocked and transmitted to the light receiving sensor 12.

Meanwhile, the light emitted by the light blocking plate 30 is installed between the lamps 13 indicating the operation state of the product. 26).

For example, when one side of the lamp 13 emits light by the selected operation, the light is not only emitted through the light emitting guide 26 formed on the front, but is dispersed in all directions.

Therefore, the scattered light is blocked by the light blocking plate 30 as shown in FIGS. 8A and 8B. Therefore, the light emitting guide 26 corresponding to the other lamps do not cause any interference so that the user can clearly recognize the operating state of the product.

Claims (7)

A light receiving sensor 12 that recognizes the received infrared rays on one side of the substrate 11 and a wrap 13 installed on the other side of the substrate 11 to indicate the operating state of the product, the substrate 11 on both sides A light receiving guide 24 having a coupling pin 21 coupled to the light receiving sensor 12 and the lamp 13 and protruding outwardly to guide the infrared light to the light receiving sensor 12; In the receiving unit consisting of a cover 20 having a light emitting guide 26 for emitting light of the lamp 13 to the outside, the end of the light emitting guide 26 is formed as a convex curved portion 24a, Structure of the infrared receiver of the remote control device, characterized in that the cut-out hole (23) on both sides of the connecting portion of the light emitting guide 26 and the cover 20 to prevent the received infrared rays from being distributed to the cover (20). 2. The structure of the infrared receiver of the remote control apparatus according to claim 1, wherein the radius of curvature (R) of the curved portion (24a) is formed to be equal to the projecting height (L) of the light receiving guide (24). The remote control apparatus according to claim 1 or 2, wherein a reflection film (24b) is placed on the outer circumference of the light receiving guide (24) to prevent the light flowing from the curved portion (26) from being lost to the outside. Infrared receiver structure. 4. The structure of the infrared receiver of claim 3, wherein the reflective film (24b) is made of an Al film. 2. The structure of an infrared receiver of a remote control apparatus according to claim 1, wherein a light shielding plate (30) is interposed between the lamps (13) to prevent light interference. According to claim 1 or 4, wherein the light shielding plate 30 in the form of a T-shape, when the number of the lamp 13 is two when installed, at right angles to the center of the light shielding plate 30 between the two lamps 13 Structure of the infrared receiver of the remote control device, characterized in that installed so as to interpose the formed intermediate plate (30b). According to claim 1 or 4, wherein when the number of the lamp 13 is installed in the shape of the light-shielding plate 30 to the T-shape, when the number of the light-shielding plate 30 is positioned obliquely to the middle to protrude at a right angle in the middle The structure of the infrared receiver of the remote control device, characterized in that it is installed so as to be located within the angle between the plate (30b) and one side plate (30a) perpendicular to it.