KR200469169Y1 - Touch Apparatus - Google Patents

Abstract

Provided is a touch device that can be independently selected for light emission or change of light emission color of each light emitting touch unit without mutual interference of light from each of the light emitting touch units, so that a user can easily identify and operate the light emitting touch unit.
The light guide block has a light guide block having a light guide surface, a light guide surface and a bottom surface, and is disposed in the vicinity of the light guide surface of the light guide block corresponding to the light guide member having at least one separation between two adjacent light guide blocks and the light guide block. And a plurality of light emitting modules derived from the light emitting surface and the light emitting blocks which are respectively installed on the bottom surface of the corresponding light guiding block and outputting a driving signal when one of the corresponding light guiding blocks is touched. It has a plurality of touch sensing module for controlling.

Description

Touch device {Touch Apparatus}

The present invention relates to a touch device, and more particularly, to a touch device that improves a push button backlight technology.

With the advancement of high-tech, the demand of home appliances is increasing in daily life, and the control interface corresponding to home appliances, for example, the remote control used for a television, an air conditioner, or the control panel used for a refrigerator, a washing machine, is diversified.

However, the functionality of home appliances is increasing and the display on touch devices is becoming more complex. When a plurality of push button icons share a light guide plate, a single push button icon may not be displayed independently, and the identification of the push button icon may be lowered. In addition, although it is common to comprise direct type light emission in which a light source is provided directly under the button icon to press each of the button icons on the touch device to emit light independently, the direct light emission has a constant light mixing distance so that light is uniform. Since it is necessary to do this, the thickness of the touch device becomes thick due to the light mixing distance, and there is a problem that the sensitivity of the touch sensor is lowered.

It is an object of the present invention to provide a touch device that is free from mutual interference of light from each of the light emitting touch units, which can independently select each light emission or change of color of the light emitting touch unit, and which can be easily identified and operated by a user. The purpose.

The present invention has a plurality of light guiding blocks provided with a light incidence surface, a light incidence surface and a bottom surface, and is provided in the vicinity of each light incidence surface of the light guiding member and the plurality of light guiding blocks between two adjacent light guiding blocks. A plurality of light emitting modules that are introduced into the light guiding block and emits light to emerge from the light exiting surface; It provides a touch device comprising a plurality of touch sensing module for outputting a signal.

In addition, the present invention has a plurality of light emitting touch units, wherein the plurality of light emitting touch units have a light guide block having at least one light incident surface, a light emitting surface and a bottom surface, and light generated adjacent to the light incident surface and guided through the light incident surface. Controlling the light emitting module by outputting a driving signal when the light emitting module derived from the light guiding block and the bottom surface of the light guiding block are detected through the light emitting surface at the same time as being incident to the block. The light guide block of the plurality of light emitting touch units has a touch sensing module, and the light guide blocks are formed at predetermined intervals with respect to the light guide members.

According to the touch device related to the present invention, the light emitting direction of the light guiding block in the light guiding member is limited by the separation interval, so that there is no mutual interference of the light emitted from each light guiding block, and each touch is operated by the user. The unit can be easily identified for smooth operation of the remote control or the control panel.

In addition, since the present invention introduces light from the side surface into the light guiding member, there is no need to install the light emitting module in the light guiding member, and the thickness of the touch device is reduced to improve the sensitivity of the touch.

1A shows an exploded schematic view of the touch device of the first embodiment related to the present invention.
FIG. 1B illustrates a local cross-sectional view of the touch device of FIG. 1A.
Figure 2 shows a schematic diagram of the operation principle of the touch sensing module according to the embodiment of the present invention.
3 is an exploded schematic view of the touch device according to the second embodiment of the present invention.
4 is an exploded schematic view of the touch device according to the third embodiment of the present invention.
5 is an exploded schematic view of the touch device of the fourth embodiment related to the present invention.
Fig. 6 shows a local stereoscopic schematic diagram of the touch device of the fifth embodiment related to the present invention.

[First Example]

1A and 1B, FIG. 1A is an exploded schematic view of a touch device according to a first embodiment of the present invention, and FIG. 1B is a local cross-sectional view of FIG. 1A, respectively. The touch device 1 according to the present invention includes a light guide member 10, a plurality of light emitting modules 12, and a plurality of touch sensing modules 14. The plurality of light emitting modules 12 and the plurality of touch sensing modules 14 may be provided on the same substrate 16. When the light guide member 10 is stacked on the substrate 16, light from the light emitting module 12 may be incident smoothly onto the light guide member 10. Hereinafter, the elements of each part of the touch device 1 will be described in more detail.

The light guide member 10 has at least one separation interval 102 for partitioning the light guide member 10 into the plurality of light guide blocks 104. That is, at least one spacing 102 is provided between two adjacent light guide blocks 104 in any of the light guide members 10. Each of the plurality of light guiding blocks 104 includes a light receiving surface 104a, a light emitting surface 104b, and a bottom surface 104c. The light guide member 10 further includes a plurality of grooves 106 for receiving the corresponding light emitting module 12. When the light guide member 10 is stacked on the substrate 16, the light emitting module 12 may be accommodated in the separation gap 102 or the groove 106.

The light incident surface 104a is close to the light emitting module 12 to introduce light from the light emitting module 12 into the light guiding block 104. The light exit surface 104b is adjacent to the light incident surface 104a and includes a diffused pattern layer 104d, which diffuses the light from the light emitting module from the light guide block 104. In practice, the light guiding member 10 is a flat light guide structure, the light exit surface 104b and the bottom surface 104c are the top and bottom planes of the flat light guide structure, and the light exit surface 104b and the bottom surface 104c are substantially close to each other. Parallel. Since the light incident surface 104a is a side surface between the top and bottom planes of the flat light guide structure, it may be adjacent to the light exit surface 104b and the bottom surface 104c, respectively. The light incident surface 104a is formed near the gap 102 or the groove 106 corresponding to the installation position of the light emitting module 12 to be configured to receive light from the light emitting module 12 so that light is guided by the light guide member 10. ) Can be smoothly entered into each of the light guiding block 104, and can be transmitted by total reflection in the light guiding member (10).

Meanwhile, each light emitting module 12 and the light guiding block 104 and the touch sensing module 14 disposed corresponding thereto may be configured as a single light emitting touch unit (see light emitting touch unit 3 of FIG. 5). The light emitting touch unit 3 may independently control light emission of the corresponding light emitting module 12 by the touch sensing module 14. In the present embodiment, each of the light guiding blocks 104 is formed on the light guiding member 10 by a spaced interval 102, but the light guiding blocks 104 of each light emitting touch unit 3 have at least a portion of adjacent light emission. Since it is connected to the light guide block 104 of the touch unit 3, the light guide member 10 is in a single state. Therefore, in the manufacturing process, the position of the substrate 16 may be determined by a single process, and the light guide block 104 may be easily positioned in each touch sensing module 14.

The scattering pattern layer 104d on the light exiting surface 104b changes the total reflection condition in the corresponding light guiding block 104 so that light can pass through the light guiding block 104 from the light exiting surface 104b, It may be a sandblasted patterning layer or a printed dot patterning layer. In addition, there is no restriction | limiting in the manufacturing method of the diffused-pattern layer 104d, The user can freely set the covering area in the light-emitting surface 104b of the diffused-pattern layer 104d.

As an example, an additional plate 20 may be further provided on the light guide member 10, or the outer surface of the touch device 1 in which the light guide member 10, the city plate 20, and the substrate 16 are stacked may be formed. The dimensions are configured to be about the same so as to be smooth. The city plate 20 has at least one light transmission area 202 for displaying a symbol icon. If the symbol icon to be expressed is large, the covering area in the light exit surface 104b of the light scattering pattern layer 104d is made correspondingly large so that the light from the light emitting module 12 passes through the light exit surface 104b. It can transmit from the light transmission area 202 on the city plate 20, and the symbol icon mentioned above is displayed by this. In addition, the illustrated plate 20 is very thin (for example, 0.2 mm). A pattern tape may be sufficient, and the adhesive surface can be directly stuck to the light guide member 10.

Of particular note is that the spacing 102 can partition the light in two adjacent light guiding blocks 104. Specifically, the separation interval 102 may be an air medium having a refractive index of about 1. Since the light guide member 10 is for guiding the progress of light, the refractive index of the light guide member 10 is usually sufficiently larger than one. That is, when light is transmitted from the several light guiding blocks 104 in the light guiding member 10 to the separation gap 102, since the light is equivalent to entering the low density medium from the high density medium, the light deviates from the tangent of the exit surface. Refraction That is, in the case of having a gap 102, the light transmitted from the light guiding block 104 is refracted toward the periphery at the exit surface and enters the light guiding block 104 adjacent to the horizontal. Therefore, the light in the light guiding block 104 can be effectively blocked by the space | interval gap 102 (for example, the width | variety of the space | interval 102) which has a suitable width | variety.

However, the present invention is not limited to the form of the spacing 102, there is no mutual interference of light in two adjacent light guide blocks 104, and the combination of the light guide member 10 and the spacing 102 can be achieved. As long as it can be, it can change and implement within the range suitable for the above-mentioned.

The light emitting module 12 mainly emits light to inform a user of each light guide block 104 corresponding to the light emitting module 12. It is preferable that the light emitting modules 12 in any two adjacent light guiding blocks 104 are not opposite to each other, and the relative distances between the light emitting modules 12 are as far apart as possible. The light emitting module 12 may be a light emitting diode or other suitable light emitting device, and is not particularly limited. As an example, the light emitting module 12 may include a plurality of light emitting diodes, and the light emitting diodes may emit light having different wavelengths. In addition, light of a predetermined wavelength may be generated by a single or a plurality of light emitting diodes.

The plurality of touch sensing modules 14 respectively contact the bottom surface 104c of the light guide member 10, and each touch sensing module 14 corresponds to several light guide blocks 104. That is, the touch sensing module 14 is installed below the light guide block 104. 2 is a schematic diagram illustrating an operation principle of a touch sensing module according to an embodiment of the present invention. As shown in FIG. 2, each touch sensing module 14 includes a touch sensing conductor 142 and a touch sensing element 144. In practice, the touch sensing element 144 may be integrated into the control chip 146, and when the corresponding light guide block 104 is touched, the touch sensing element 144 detects the detected touch sensing conductor 142. The driving signal is output to the light emitting module 12 based on the equivalent capacitance change amount, and the lighting method of the light emitting module 12 is determined. In addition, the control chip 146 may further integrate the touch sensing element 144 of each touch sensing module 14 in the touch device 1, and when the other light guide block 104 is touched, the control chip 146 detects the internal touch sensing element 144 to determine which light emitting module 12 is to be correspondingly driven. In this way, the use of the circuit element can be saved by sharing the control chip 146. When the city plate 20 is installed above the light guiding member 10 when the user touches the symbol icon on the city plate 20, the touch sensing module 14 may show the city plate 20 and the light guiding block. It is determined whether or not the light guide block 104 has been touched based on the amount of change in the equivalent capacitance value of the 104 and other peripheral elements. When it is determined that the light guiding block 104 has been touched, the corresponding touch sensing module 14 outputs a driving signal to the light emitting module 12 and controls the need and necessity of light emission by the light emitting module 12, or the light emitting module The wavelength range of light by (12) is changed. As a result, the touch sensing module 14 may determine the lighting method of the light emitting module 12.

In practice, the touch sensing conductor 142 of the touch sensing module 14 has a sensing range 142a (see FIG. 1A) that can effectively sense a user's touch area. As one example, the dimensions of the sensing range 142a are in the range of about 10 mm in diameter. As described above, when the capacitive sensing technique is applied, the overall thickness can be greatly reduced, and at the same time, the same sensing range 142a can be sensed by the smaller touch sensing module 14, The sensing sensitivity of the touch sensing module 14 may be effectively improved. In general, when determining whether the light guide member 10 has been touched, it is common that the equivalent capacitance value detected by the touch sensing module 14 reaches 13 pF as a standard. When the equivalent capacitance change amount detected by the touch sensing module 14 does not reach 13 pF, it is determined that the touch is not touched. On the contrary, when the equivalent capacitance change amount detected by the touch sensing module 14 is larger than 13 pF, it is determined that the touch is sensed. In addition, the touch sensing conductor in the conventional touch sensing module is generally set to 10 mm or more in diameter so as to effectively detect the above-mentioned equivalent capacitance change amount. However, when the present invention is applied to the light guiding member 10, if the diameter of the touch sensing conductor 142 in the touch sensing module 14 is 8 mm, the same equivalent capacitance change amount may be detected. That is, the present invention has a cost reduction effect of the product because it is possible to reduce the placement area of the touch sensitive conductor 142 by 36%.

Moreover, the board | substrate 16 which concerns on this invention is a printed circuit board (PCB), The circuit element of another function may be provided. As an example, when the touch device 1 is used as a control switch, the substrate 16 can be combined with a functional circuit corresponding to the control switch. In practice, the circuit board may be freely exchanged by a person skilled in the art, and may be a flexible flexible printed circuit board or an ineffective rigid printed circuit board.

In particular, it should be noted that the light emitting module 12 related to the present invention is not under the light guide member 10, but on one side of the light guide member 10 (that is, each light emitting module 12 has a light incident surface of the light guide block 104). 104a), the overall thickness is greatly reduced. When a conventional light emitting module is provided under the light guiding member, the total thickness of the light guiding member and the light emitting module is about 2. 8 mm. However, according to the present invention, since the light emitting module 12 is installed on one side of the light guiding member 10, the total thickness of the light guiding member 10 (about 0.6 mm) and the drawing plate 20 (about 0.2 mm) is 0.8 mm. It is greatly reduced. In addition, the thickness of the touch sensing module 14 is only 0.035 mm-0.712 mm, and there is no need to add the thickness of the substrate 2.

In addition, the plurality of light emitting diodes may be provided in the grooves 106 or in the gaps 102, may be provided in the grooves 106 and the gaps 102, and are not particularly limited. Each light emitting diode may be electrically connected to one light guiding block 104 respectively. In addition, although the groove 106 is provided in the circumference | surroundings of the light guide member 10 in embodiment, it is not limited to this, What is necessary is just to design suitably.

When the touch device 1 according to the present invention is applied to a remote control, when a user touches a symbol icon corresponding to the city plate 20, the light display of the touched symbol icon can be changed and a predetermined function is controlled. can do. For example, when the touch device 1 according to the present invention is applied to an air conditioner remote control, the symbol icon corresponds to the function of opening / closing the air conditioner, opening / closing the dehumidification, raising or lowering the temperature, or indicating the temperature. After the user touches the symbol icon for opening and closing the air conditioner, the symbol icon can display the opening and closing of the air conditioner by changing the color, whereby the user can more easily identify the current use state of the air conditioner. That is, by combining the touch device 1 according to the present invention with a conventional remote control or control panel and improving the display method of each function key on the remote control or the control panel, the user can more easily control each function on the remote control or the control panel. Can be distinguished.

Second Embodiment

In order to prevent light from being transmitted to the adjacent light guiding block 104, it is preferable that the light incident surfaces 104a of the adjacent light guiding block 104 do not face each other. Between the light incident surface 104a, not only the air medium in the space | interval gap 102 but other light blocking structures may be interposed. 3 is an exploded schematic view of the touch device according to the second embodiment of the present invention. The biggest difference from the first embodiment is that the light blocking member 18 is further provided on the side surface 10a of the light guide member 10 of the touch device 1a in the second embodiment.

In practice, the light blocking member 18 may be a light blocking tape for covering the side surface 10a around the light guide member 10 such that light is emitted from only the light exit surface 104b of each light guide block 104. . In addition, the light blocking member 18 may be provided with a plurality of slits in response to the light emitting module 12 so that light from the light emitting module 12 is incident on the light guide block 104 of the light guide member 10.

[Third Example]

4 is an exploded schematic view of the touch device according to the third embodiment of the present invention. The biggest difference from the second embodiment is that the light blocking member 18 is moved to the touch device 1b of the third embodiment so that the light beam is emitted from only the light exiting surface 104b of each light guide block 104. The point is provided at the clearance gap 102 without making direct contact with (10). In practice, the light blocking member 18 of the touch device 1b of the third embodiment may be a non-light-transmitting material provided on the substrate 16 to block a part of light that has passed through each light guide block 104. good. That is, the light blocking member 18 restricts the transmission of light to a predetermined region (for example, a single light guiding block 104), so that the light is emitted from only the predetermined region by the light exiting surface 104b. Of course, in the present invention, by manufacturing the case in which the touch device 1b is packaged as part of the light blocking member 18, the manufacturing cost of the light blocking member 18 can be saved.

[Fourth Example]

5 is a plan view of a part of a touch device of a fourth embodiment related to the present invention. The difference between the touch device 1c of the fourth embodiment and the touch device 1 of the first embodiment is that the light guiding blocks 104 'of the touch device 1c are not connected to each other. Is a point where a plurality of light guide blocks 104 'are dispersed. Since the position and function of the other elements of the fourth embodiment are the same as in the first embodiment, detailed description thereof will be omitted. Moreover, the space | interval 102 is extended to the light guide block 104 ', and has the extending | stretching part for accommodating a light emitting diode. In the present embodiment, the groove 106 shown in the drawing is formed, but is not particularly limited and may be appropriately designed as desired.

Further, as described in the first embodiment, the light guiding block 104 ', the light emitting module 12 and the touch sensing module 14 (see Fig. 1A) can be configured as a single light emitting touch unit 3. Since the light guiding blocks 104 ′ of the light guiding member 10 ′ are independent of each other, each light emitting touch unit 3 can be made an independent object, and the light guiding block 104 ′ is previously applied to the manufacturing process for the touch sensing module. After coupling to 14, the position on the substrate 16 can be determined.

[Fifth Embodiment]

6, the groove 106 for accommodating the light emitting module 12 may have a predetermined shape. As an example, grooves 106 are recessed at the edges of the light guiding block 104 "so that the light emitting module 12 is disposed corresponding to the grooves 106. The touch device 1d of the fifth embodiment is formed. The difference from the fourth embodiment is that each light guide block 104 " shape may have a corresponding light guide block 104 " in response to the light emitting module 12. Most of the light guide block 104 " The light receiving surface 104a may be provided with a groove 106 for enclosing or covering the light emitting module 12 so that the light smoothly enters the light guiding block 104 ″. That is, the groove 106 may not only accommodate the light emitting module 12 but may also contribute to light reception of the light incident surface 104a.

The present invention may be rectangular, semi-circular, triangular, or any other suitable form as long as it contributes to the light reception of the light incident surface 104a without limiting the shape of the groove 106.

According to the touch device according to the present invention, by installing the light emitting module on the side of the light guide member, the thickness of the entire touch device can be greatly reduced.

In addition, when the capacitive sensing technology is applied, the sensing sensitivity of the touch sensing module can be effectively improved.

In addition, the present invention can limit the light emission direction in each light guiding block by providing a predetermined interval so that mutual interference of light emitted from the light guiding block does not occur.

When the user operates, the light from the light guide block can be more easily identified, and the remote controller or other types of controllers to which the present invention is applied can be operated smoothly.

1, 1a, 1b, 1c, 1d touch device
3 luminous touch unit
10, 10 ＇light guide member
12 light emitting module
10a side of light guide member
14 Touch Sensing Module
16 boards
18 light blocking member
102 separation interval
104, 104 ', 104 "light guide block
104a light incident surface
104b exit face
104c bottom
104d diffuse pattern
106 home
142 Touch Sensing Conductor
142a detection range
144 touch sensing elements
146 control chip
20 city plates
202 light transmission area
9 touch device
90 light source
92 light guide plate
94 pressing button icons
96 touch sensor

Claims (8)

A light guiding member including a plurality of light guiding blocks having a light receiving surface, a light emitting surface, and a bottom surface, the light guiding member having at least one separation distance between two adjacent light guiding blocks;
A plurality of light emitting modules corresponding to each of the light guiding blocks and installed in the vicinity of the light receiving surface of each of the light guiding blocks to emit light from the light exiting surface while being introduced into the light guiding block; And,
A plurality of light guide blocks are provided on the bottom of each of the light guiding blocks to detect a touch of one of the light guiding blocks. Includes a touch sensing module,
A portion of each of the light guide blocks is connected to each other so that the light guide member is a single plate,
And the light emitting surface has a scattering pattern layer for guiding light from the light emitting module from the light guiding block. A touch device comprising a plurality of light emitting touch units,
Each of the plurality of light emitting touch units includes:
A light guide block having at least one light incident surface, a light emitting surface, and a bottom surface;
A light emitting module adjacent to the light incident surface and the generated light enters the light guiding block through the light incident surface and simultaneously withdraws from the light guiding block through the light exit surface;
A touch sensing module installed on the bottom surface to detect the touch of the light guide block and outputting a driving signal to control the light emitting module;
The light guide blocks of the light emitting touch units are formed in the light guide members at predetermined intervals.
A portion of each of the light guide blocks is connected to each other so that the light guide member is a single plate,
And the light emitting surface has a scattering pattern layer for guiding light from the light emitting module from the light guiding block. delete The method of claim 1,
A light blocking member provided within the separation interval to block light derived from the light guiding blocks in the plurality of light emitting touch units, wherein the light blocking member is located within the separation interval and at least one of the light guiding members; Touch device, characterized in that the light-blocking tape that can be attached to one side. The method of claim 1,
Each touch sensing module
A touch sensing conductor for sensing whether the corresponding light guiding block is being touched by the operator;
When the corresponding light guiding block is touched by the operator, the drive signal for detecting the equivalent capacitance change amount of the touch sensing conductor and determining the lighting method of the corresponding light emitting module based on the equivalent capacitance change amount, Touch device comprising a touch sensing element for outputting to the light emitting module. The method of claim 1,
It further comprises a city plate having a plurality of light transmission area for displaying a symbol icon and installed on the light guide member,
The plurality of light transmissive regions are disposed corresponding to each of the light guiding blocks such that light from the corresponding light emitting module passes from the corresponding light transmissive regions in the plurality of light transmissive regions through the light exit surface of the corresponding light guiding block. Touch device, characterized in that the transmission. The method of claim 1,
The light guide block has a groove formed on the light incident surface, and the plurality of light emitting modules are installed in the groove. The method of claim 2,
Further comprising a light blocking member disposed in the spacing,
The light blocking member separates light guided from each of the light guide blocks,
The light guide member further includes a plurality of side surfaces,
And said light blocking member is a light blocking tape disposed at said spacing and attached to at least one of said side surfaces.

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