KR101192392B1 - Apparatus for testing flatness of window for touch screen module - Google Patents

Abstract

PURPOSE: A device for testing the flatness of tempered glass for a touch screen module is provided to automatically test the flatness of tempered glass and to quickly and conveniently inform the existence of the failure of the tempered glass to an inspector. CONSTITUTION: A device for testing the flatness of tempered glass for a touch screen module comprises a body(110), a contact sensor(120), a controlling unit, and a display(140). The body comprises a seating unit(111) in which an edge portion of tempered glass(1) and a flat portion having different height with the tempered glass. The contact sensor is installed to be elastically projected at height lower than the seating unit at one spot of the flat portion and becomes inserted into the inside of the body when contacting to a bottom of the tempered glass. The controlling unit is electrically connected to the contact sensor, thereby confirming the existence of contact with the tempered glass. The controlling unit transmits electrical output signals according to a result of the confirmation. The display unit operates with output signals of the controlling unit, thereby informing the failure existence of the flatness of the tempered glass.

Description

Flatness inspection device for tempered glass for touch screen module {APPARATUS FOR TESTING FLATNESS OF WINDOW FOR TOUCH SCREEN MODULE}

The present invention relates to a flatness inspection device for tempered glass for touch screen modules, and more particularly, to automatically and flatly check the flatness of the tempered glass used in the touch screen module to determine whether the tempered glass is defective. The present invention relates to a flatness inspection device for tempered glass for a touch screen module.

As the types of electronic devices are diversified, various technologies have been proposed that can reduce the size of electronic devices but increase the size of display screens. BACKGROUND With the miniaturization of electronic devices, electronic devices that recognize a user's input through a touch input device are increasing. In particular, touch screen modules having an input function on a display screen have been applied to various devices including portable electronic devices.

As a typical portable communication terminal, the mobile phone is becoming more popular as a 'smart phone' that integrates various functions such as computer functions and traditional call functions according to the continuous evolution.

Since smartphones are equipped with various applications, including the Internet, to execute a wide variety of functions in addition to the intrinsic call functions, the dome switch has been widely used in mobile phones as an input device for inputting various operations and data. The keypad of the type is limited, and for this reason, touch input devices represented by touch screens have been widely applied to smart phones.

The touch screen module can be used for various portable terminals such as MP3, PDA, PMP, PSP, handheld game consoles, DMB receivers including mobile phones such as smartphones, navigation, industrial terminals, notebook computers, financial automation devices, game machines, etc. As well as a monitor, it is widely used as an input means for various electric and electronic devices, ranging from various home appliances such as refrigerators, microwave ovens and washing machines.

As is known, the touch screen module includes a display unit on which predetermined contents are displayed, a transparent electrode film and a transparent electrode which are stacked on the display unit to input contents displayed on the display unit below when a finger or the like is touched (pressurized). It is made of a transparent tempered glass (window) is laminated on the film to protect the transparent electrode film from the outside, there is a capacitive method, resistive film method, infrared method, ultrasonic method, etc., depending on the structure and operation principle.

In the capacitive touch screen, there is a capacitive touch sensor that detects only the contact (approach) of a conductor (eg, a finger), and a capacitive pressure sensor that detects the magnitude of the pressure applied by the contact.

The former capacitive touch sensor is a structure in which a pole plate (for example, a transparent electrode film such as Indume Tin Oxide (ITO)) is laminated (coated) on a substrate (for example, a synthetic resin) in a predetermined array (for example, a matrix array). A touch screen that generates an input signal corresponding to a touch position by measuring parasitic capacitance generated when a conductor (for example, a finger) approaches (or touches) a pole plate and detecting a corresponding touch position (coordinate). As a contacting object, only non-conductors (eg, fingers) can be used, and only the contact can be detected but the magnitude of the applied pressure cannot be detected.

The latter capacitive pressure sensor has a structure in which the upper and lower pole plates, for example, are arranged in a matrix, spaced apart from each other on a substrate by varying the pressure between the upper and lower pole plates when a pressure is applied to the surface insulator (cover panel). It is a touch screen that generates an input signal corresponding to the position and magnitude of the pressure by measuring the change in capacitance generated while detecting the magnitude of the pressure applied together with the corresponding touch position (coordinate). By pressing a predetermined position of the touch screen, the input is performed, and different input signals can be generated according to the magnitude of the applied pressure as well as the touch position.

Thus, in order to protect the transparent electrode film and the display unit which play an important role as a touch screen from external impact or contamination, a tempered glass is laminated on the uppermost layer of the touch screen module. Maintaining the degree does not lower the brightness or contrast of the touch screen, thereby improving user readability and visibility.

Therefore, the tempered glass for the touch screen module must go through the flatness test, conventionally, the flatness of the tempered glass was inspected through a manual test as shown in FIG.

Figure 1 is a perspective view schematically showing a flatness inspection device of the tempered glass for a conventional touch screen module.

As shown in FIG. 1, conventionally, a main body 10 having a substantially hexahedron shape is provided to inspect the flatness of the tempered glass 1, and an elastic body such as rubber or silicon is provided on an upper surface of the main body 10. A plurality of inspection protrusions 11 are formed to protrude.

The inspection protrusion 11 is not inserted into the upper surface of the main body 10 but is fixed in a protruding form, but since the inspection protrusion 11 is made of an elastic body, when the tempered glass 1 is raised and pressed, the amount of protrusion may be reduced, but protruding. Instead of reducing the amount, there is a characteristic that the contact area in contact with the bottom of the tempered glass (1) is increased.

As such, when the tempered glass 1 to be examined is placed on the inspection protrusion 11 protruding at various points of the upper surface of the main body 10, the inspection protrusion 11 is pressed while contacting the bottom surface of the tempered glass 1. In this case, if the tempered glass 1 is not bent at all and is flat, the contact area of the inspection protrusion 11 pressed and contacted by the tempered glass 1 will be the same anywhere, and this contact area will be transparent tempered glass ( It can be visually identified through 1).

However, if the tempered glass (1) is bent in a convex downward shape and the flatness is poor, the contact area of the inspection protrusion 11 located at the center of the upper surface of the main body 10 is large, but the inspection protrusion located at the edge of the main body ( 11) The contact area of 11) may be smaller than the center or not in contact at all. The inspector examines the flatness of the tempered glass by looking at the contact area of the test projection projected through the tempered glass.

However, the conventional tempered glass flatness inspection apparatus as described above is very inconvenient because the inspector must visually determine the flatness of the tempered glass by looking at the contact area of the inspection projections, and thus it is necessary to rely on the experience or sense of the inspector. There is a problem in that precision and reliability are degraded.

In addition, the conventional tempered glass flatness inspection device is a long time use, the inspection projections made of an elastic body is worn and the protrusion amount of each inspection projection is different, as a result there is a problem that the flatness inspection of the tempered glass is incorrectly determined.

The present invention is to solve the problems as described above, the purpose is to automatically check the flatness of the tempered glass for the touch screen module so that the inspector can easily determine whether the tempered glass defects work efficiency of flatness inspection To increase the accuracy and reliability of the inspection.

In addition, another object of the present invention is to perform a long-term inspection to easily adjust even if the inspection measurement unit deviates from the reference value to prevent the misalignment flatness test and always maintain a constant reliability.

In order to solve the above-mentioned problems,

It is a device to automatically check the flatness of the tempered glass used in the touch screen,

A hexahedron-shaped body having a seating portion on which an edge of the tempered glass is placed, and a flat portion recessed in a lower portion to form a stepped portion from the seating portion and having a flat upper surface to generate a height difference with the tempered glass; A contact detection sensor installed to be elastically protruded to a lower height than a seating portion on any one of the flat parts, and being pressed into and inserted into the bottom surface of the tempered glass; A control unit electrically connected to the touch detection sensor to determine whether the tempered glass is in contact and to transmit an electrical output signal according to the determination result; It is operated by the output signal of the control unit, and provides a flatness inspection device for the tempered glass for touch screen module comprising a; display unit for informing the user whether the tempered glass flatness is poor.

Wherein the touch sensor is characterized in that installed in the center of the flat portion.

In addition, the touch sensor is characterized in that it is further installed near each of the four corners located in each diagonal direction with respect to the center of the flat portion.

On the other hand, the display unit has a normal display lamp which is turned on to indicate that the flatness of the tempered glass is normal when the touch detection sensor is not pressed, and a defect that is turned on to indicate that the flatness of the tempered glass is poor when the touch detection sensor is pressed. A display lamp is provided.

In addition, the display unit is provided with a notification lamp that is turned on to indicate that the flatness of the tempered glass is bad when the contact detection sensor is pressed.

In addition, the display unit is characterized in that the buzzer is further provided through the sound that the flatness of the tempered glass when the contact detection sensor is pressed.

On the other hand, the main body is characterized in that the measurement bar for measuring whether the height of the projecting height of the contact sensor falls within the reference height range.

In addition, a guide line parallel to the flat portion is formed on the outer wall surfaces facing each other of the main body, and both ends of the measuring bar are fitted into the guide line and move along the guide line, and are rotated when reaching the end of the guide line. The bar is characterized in that the position is moved toward the side wall of the body on the flat portion.

Wherein the guideline is characterized in that the sliding groove or the sliding rail.

In addition, the main body is characterized in that the micrometer is connected to the contact detection sensor to adjust the height of the contact detection sensor protruding onto the flat portion.

According to the present invention, by automatically inspecting the flatness of the tempered glass so that the inspector can quickly and conveniently know whether the tempered glass is defective, the work efficiency of the flatness test is improved, and in particular, the experience and feeling of the inspector as in the prior art. Since it does not need to rely on, there is an excellent effect of greatly increasing the accuracy and reliability of the inspection.

In addition, according to the present invention, even if the projected height of the touch sensor is changed by performing the flatness test for a long time, the reference value of the touch sensor can be easily measured and corrected to the reference value range, so that the reliability of the tempered glass flatness test is high. There is a further advantage.

Figure 1 is a perspective view schematically showing a flatness inspection device of the tempered glass for a conventional touch screen module,
Figure 2 is a perspective view showing a flatness inspection device of the tempered glass for the touch screen module according to the present invention,
3 is a control block diagram showing a control relationship of the inspection apparatus according to the present invention;
4a and 4b is an operational state diagram schematically showing the measurement of the height of the protrusion of the touch sensor using a measuring bar according to the present invention,
Figure 5 is a cross-sectional view showing a structure for adjusting the height of the touch sensor using a micrometer according to the present invention.

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

Figure 2 is a perspective view showing a flatness inspection device of the tempered glass for the touch screen module according to the present invention, Figure 3 is a control block diagram showing the control relationship of the inspection device according to the present invention, Figures 4a and 4b is the present invention FIG. 5 is a cross-sectional view illustrating a structure for adjusting the height of the touch sensor using a micrometer according to the present invention. FIG.

First, the present invention will be described with reference to FIGS. 2 and 3, and the flatness inspection apparatus of the tempered glass for the touch screen module according to the present invention is largely the main body 110, the contact sensor 120, and the controller 130. And the display unit 140.

As shown in FIG. 2, the main body 110 has a substantially hexahedral shape as a whole, and the main body 110 is provided with a seating portion 111 and a flat portion 112.

The seating portion 111 is a portion on which the edge of the tempered glass 1 to be inspected is placed, and when the tempered glass 1 is placed on the main body 110, the seating portion 111 is connected to the edge of the tempered glass 1. Supporting the tempered glass (1) while in contact.

The flat portion 112 is recessed a predetermined depth downward to form a stepped portion from the seating portion 111, and the upper surface of the recessed state is formed flat to generate a predetermined height difference between the tempered glass 1 It is a part to do.

That is, since the seating portion 111 is formed at a height as high as a predetermined height from the flat portion 112, when the tempered glass 1 is placed on the seating portion 111, the bottom of the flat portion 112 and the tempered glass 1 are lowered. The height difference by the height of the mounting portion 111 is generated between.

On the other hand, the touch sensor 120 is configured to be elastically protruded to a lower height than the seating portion 111 on any point of the flat portion 112, the touch sensor 120 is a tempered glass ( When contacted with the bottom surface of 1) is pressed by the tempered glass (1) is inserted into the interior (lower direction) on the flat portion 112.

Here, the contact sensor 120 is sufficient to be installed at any point on the flat portion 112, which is advantageous for measuring the bending of the tempered glass (1), typically the tempered glass (1) is convex down when the defect Most of the bending in the form and the lowest point of the most convex tempered glass (1) is generally the center of the tempered glass (1), so the contact detection for contact with the lowest point of the convex tempered glass (1) The position of the sensor 120 is preferably set to the center of the flat portion 112.

Therefore, when the tempered glass 1 placed on the seating part 111 is flat, the contact sensor 120 is not pressed by the tempered glass 1, but the tempered glass 1 is convex downward. In the case of a bad bend to contact detection sensor 120 is pressed.

In addition, the tempered glass 1 also generates some unusual defects that are curved in a wave shape. In this case, the tempered glass 1 may have convex points below.

In order to detect such a wavy tempered glass 1, the touch sensor 120 is preferably installed in a plurality of other places as well as the center of the flat portion 112, as shown in FIG. The touch sensor 120 may be further installed near four corners positioned in each diagonal direction with respect to the center of the flat part 112.

Although the embodiment of the present invention has been implemented that the position of the contact detection sensor 120 can be installed at the point as described above, this has been described an exemplary position in consideration of the bending of the tempered glass (1) that occurs conventionally According to the needs of those skilled in the art, the position of the touch sensor 120 can be changed as much as possible.

On the other hand, the control unit 130 is electrically connected to the touch sensor 120 to determine whether the touch sensor 120 is in contact with the bottom surface of the tempered glass (1) by a signal input from the touch sensor 120. After the determination, the predetermined electrical output signal is sent to the display unit 140 according to the determination result.

The display unit 140 is configured to be operated by an output signal of the controller 130, and the display unit 140 notifies the user (inspector) whether the flatness of the tempered glass 1 is poor.

That is, when the contact detection sensor 120 is pressed by the tempered glass 1 when inspecting the flatness of the tempered glass 1, the controller 130 determines that the tempered glass 1 is defective and sends an output signal. By operating the display unit 140, the display unit 140 may inform the user whether the tempered glass 1 is defective in various forms as described below.

First, as one of various embodiments of the display unit 140, as shown in FIG. 2, a normal display lamp 141 and a defective display lamp 142 may be provided in the display unit 140.

The normal display lamp 141 is turned on to indicate that the flatness of the tempered glass 1 is normal when the touch sensor 120 is not pressed. If the touch sensor 120 is not pressed, the normal display lamp is pressed. 141 is always lit. In this case, when the normal display lamp 141 is turned on, it indicates that the tempered glass 1 is normal (passed), and the normal display lamp 141 may be implemented in blue.

The defective display lamp 142 is turned on to indicate that the flatness of the tempered glass 1 is poor when the contact detection sensor 120 is pressed by the tempered glass 1, and the defective display lamp 142 is turned on. When turned on, it indicates that the tempered glass 1 is bent in a bad state, and the bad display lamp 142 may be implemented in red.

On the other hand, the display unit 140 may be implemented in another form, which is notified to the user when the tempered glass (1) is normal, but notified only when the failure, the display unit 140, one notification lamp 143 Only can be arranged.

The notification lamp 143 is turned on to indicate that the flatness of the tempered glass 1 is bad when the contact detection sensor 120 is pressed, the tempered glass in the state that the notification lamp 143 is turned off ( 1) means normal (passed).

In addition, the display unit 140 may be provided with a buzzer 144 for additionally notifying through the sound that the flatness of the tempered glass 1 is bad when the touch sensor 120 is pressed in addition to the above-described configuration.

Therefore, the user (inspector) can quickly and easily identify the defect of the tempered glass 1 through the buzzer 144 together with the defect display lamp 142 or the notification lamp 143.

On the other hand, when the contact detection sensor 120 according to the present invention also used for a long time, the contact surface is worn and despite the fact that the warp of the tempered glass (1) is not in contact with the bottom surface of the tempered glass (1) well pass judgment well You can't.

In addition, when the height of the contact detection sensor 120 installed to elastically protrude on the flat part 112 is set incorrectly, it may be difficult to determine the inspection of the tempered glass 1, as shown in FIG. 2 to solve this problem. The main body 110 is provided with a measurement bar 150 for measuring whether the height of the protrusion of the contact detection sensor 120 falls within the reference height range.

The measurement bar 150 is located at one side of the main body 110 so as not to cover the flat portion 112 when the flatness inspection of the tempered glass 1 is performed, and the protrusion height of the touch sensor 120 is measured. Only when the flat portion 112 is disposed above it is measured whether the height of the protrusion of the touch sensor 120 belongs to the reference value.

The measuring bar 150 is provided with a ruler directed downward to measure the distance between the measuring bar 150 and the touch sensor 120 or to measure the height of the touch sensor 120 protruding from the flat portion 112. Since this is obvious to those skilled in the art, it will not be shown separately in the drawings.

On the other hand, the measurement bar 150 is located on one side of the main body 110 when the flatness of the tempered glass 1 is inspected so as to be disposed above the flat portion 112 when measuring the height of the protrusion of the contact detection sensor 120. As shown in FIGS. 2, 4A, and 4B, guide lines 160 parallel to the height of the flat portion 112 are formed on the outer wall surfaces of the main body 110 that face each other. Both ends are inserted into the guide line 160 and move along the guide line 160. When both ends of the measuring bar 150 reach the end of the guide line 160, the ends thereof are rotated so that the measuring bar 150 is flat. ) Is moved toward one wall surface of the main body 110.

That is, as shown in Figure 4a, when performing the flatness test of the tempered glass 1, the measuring bar 150 is rotated at the end of the guide line 160 to cover the flat portion 112 so that the main body ( It is located on one side wall of the 110, when to measure the height of the protrusion of the contact sensor 120 is rotated to the top of the flat portion 112 at the end of the guide line 160, as shown in Figure 4b The measurement bar 150 moves along the guide line 160 to be positioned above the contact detection sensor 120.

Here, the guide line 160 may be implemented as any one of a sliding groove or a sliding rail.

On the other hand, as described above, as a result of measuring the protrusion height of the touch sensor 120 through the measurement bar 150, when the protrusion height of the touch sensor 120 is out of the reference height range as shown in Figure 5 As described above, the height of the touch sensor 120 may be adjusted using the micrometer 170 provided at one side of the main body 110.

The micrometer 170 is connected to the touch sensor 120 is a configuration that can easily adjust the height of the touch sensor 120 protruding onto the flat portion 112.

Therefore, when the contact detection sensor 120 is worn out for a long time, the contact detection sensor 120 may be further protruded from the flat part 112 using the micrometer 170.

On the other hand, since the tempered glass (1) is a lightweight material and the load is very small, even if the tempered glass (1) is placed on the seating portion 111 may not be in close contact with the seating portion 111, the tempered glass (1) This can lead to problems that cannot be checked for correct flatness.

Therefore, the edge of the tempered glass 1 is in close contact with the seating portion 111 to increase the reliability of the flatness inspection, at least one of the seating portion 111 or the flat portion 112 of the tempered glass It is preferable that a vacuum suction hole 180 is formed to operate the vacuum pressure so that the edge of (1) is in close contact with the seating portion 111.

Here, the vacuum suction hole 180 may be formed directly on the seating portion 111, as shown in Figure 2, is formed in the flat portion 112 so that the vacuum pressure is applied to the bottom surface of the tempered glass (1) In addition, if necessary, the vacuum suction hole 180 may be formed in both the mounting portion 111 and the flat portion 112, which may be appropriately selected according to the needs of the practitioner.

In addition, the vacuum pressure acting on the vacuum suction hole 180 is sufficient if the edge of the tempered glass 1 is in close contact with the seating portion 111, and it does not affect the original flatness of the tempered glass at all, rather than a complete vacuum. It is good to have a partial vacuum pressure. For example, since the atmospheric pressure is 760 mmHg, when the vacuum pressure is set so that a partial vacuum of about 500 to 700 mmHg acts, the edge of the tempered glass 1 closely adheres to the seating part 111 without affecting the curvature of the tempered glass 1 at all. You can do that.

Here, the vacuum pressure range of the vacuum suction hole 180 can be appropriately changed according to the needs of the practitioner. In addition, the vacuum suction hole 180 is connected through a separate vacuum unit and a flow path, and the vacuum pressure generated in the vacuum unit acts around the vacuum suction hole 180. Since the vacuum suction hole 180 is connected to the vacuum unit to operate the vacuum pressure, it will be apparent to those skilled in the art, and thus, a detailed description thereof will be omitted.

As mentioned above, although this invention was demonstrated in detail using the preferable Example, the scope of the present invention is not limited to the specific Example described, and the person of ordinary skill in the art is not limited within the scope of this invention. Substitution and modification of the components are possible, which also belongs to the rights of the present invention.

1: tempered glass 110: body
120: touch sensor 130: control unit
140: display unit 141: normal display lamp
142: bad display lamp 143: notification lamp
144: buzzer 150: measuring bar
160 guideline 170 micrometer
180: vacuum suction hole

Claims (11)

A device for automatically checking the flatness of the tempered glass (1) used for the touch screen,
A height difference with the tempered glass 1 is formed by recessing a predetermined depth to the bottom of the seating portion 111 on which the edge of the tempered glass 1 is placed, and a stepped portion from the seating portion 111 and forming an upper surface flat. A main body 110 having a hexahedron shape having a flat portion 112 formed therein;
A contact detection sensor 120 installed to elastically protrude to a lower level than the seating part 111 on any one point of the flat part 112 and pressed when inserted into the bottom surface of the tempered glass 1;
A controller 130 electrically connected to the touch sensor 120 to determine whether the tempered glass 1 is in contact, and to transmit an electrical output signal according to the determination result;
It is operated by the output signal of the control unit 130, and includes a display unit 140 for informing the user whether or not the flatness of the tempered glass (1),
The main body 110 has a flatness inspection device of the tempered glass for a touch screen module, characterized in that the measuring bar 150 for measuring whether the height of the protrusion of the contact sensor 120 is within the reference height range is provided. The flatness inspection apparatus of the tempered glass for a touch screen module according to claim 1, wherein the touch sensor 120 is installed at a central portion of the flat portion 112. The tempered glass for the touch screen module of claim 2, wherein the touch sensor 120 is further installed near four corners positioned in each diagonal direction with respect to the center of the flat part 112. Flatness tester. The display unit 140 has a normal display lamp 141 which is turned on to indicate that the flatness of the tempered glass 1 is normal when the contact detection sensor 120 is not pressed, and the contact detection sensor ( Flatness inspection device of the tempered glass for the touch screen module, characterized in that the bad display lamp 142 is provided to indicate that the flatness of the tempered glass (1) is turned on when 120 is pressed. The touch panel of claim 1, wherein the display unit 140 is provided with a notification lamp 143 which is turned on to indicate that the flatness of the tempered glass 1 is poor when the touch sensor 120 is pressed. Flatness inspection device for tempered glass for screen module. The touch panel according to claim 4 or 5, wherein the display unit 140 is provided with a buzzer 144 for additionally informing the user that the flatness of the tempered glass 1 is poor when the touch sensor 120 is pressed. Flatness inspection device for tempered glass for screen module. delete 2. The guide line 160 parallel to the flat portion 112 is formed on outer wall surfaces of the main body 110 that face each other, and both ends of the measurement bar 150 are guide lines 160. It is inserted into the movement along the guideline 160 and reaches the end of the guideline 160 is rotated so that the measuring bar 150 is moved from the flat portion 112 toward the one side wall of the main body 110 Flatness inspection device for tempered glass for touch screen module. The flatness inspection apparatus of tempered glass for a touch screen module according to claim 8, wherein the guide line is a sliding groove or a sliding rail. The method according to claim 1, wherein the main body 110 is provided with a micrometer 170 is connected to the contact detection sensor 120 to adjust the height of the contact detection sensor 120 protruding onto the flat portion 112 Flatness inspection device for tempered glass for the touch screen module. The vacuum suction hole of claim 1, wherein a vacuum pressure acts on at least one of the seating part 111 or the flat part 112 so that the edge of the tempered glass 1 is in close contact with the seating part 111. Flatness inspection device of the tempered glass for the touch screen module, characterized in that the 180 is formed.

Images