KR20110021742A - Method for evaluating the luminance nonuniformity of the glass substrate for display, the manufacturing method of the glass substrate for display, and the glass substrate for display in which a luminance nonuniformity is hard to generate | occur | produce - Google Patents

Abstract

The glass substrate 4 for a display is provided between the 1st polarizing plate 2 arrange | positioned in the direction to which light is irradiated from the light source 1, and the 2nd polarizing plate 3 arrange | positioned so that it may orthogonally cross a polarization axis of the 1st polarizing plate 2 Evaluation of the luminance nonuniformity of the glass substrate for a display which inserts and detects the light which permeate | transmits the 1st polarizing plate 2, the display glass substrate 4, and the 2nd polarizing plate 3 from the light source 1, and evaluates a brightness nonuniformity. As a method, the glass substrate 4 for a display is surface-contacted to the 1st polarizing plate 2 and the 2nd polarizing plate 3.

Description

TECHNICAL FOR EVALUATING LUMINANCE NONUNIFORMITY OF DISPLAY GLASS SUBSTRATE, METHOD FOR MANUFACTURING DISPLAY GLASS SUBSTRATE, AND DISPLAY GLASS SUBSTRATE WHEREIN LUMINANCE NONUNIFORMITY IS NOT EASILY GENERATED}

The present invention relates to a glass substrate for display which prevents luminance unevenness generated in the display panel.

In view of space saving, flat panel displays have recently been used in place of CRT displays that have been widely used. In particular, since liquid crystal displays are relatively power-saving, they are used in various display devices such as televisions, cellular phones, portable game consoles, and car navigation systems.

In a liquid crystal display, a liquid crystal sandwiched in a glass substrate for a liquid crystal display in which a transparent electrode is disposed between a set of orthogonal polarizers is disposed, and the alignment of liquid crystal molecules is changed by application of a voltage between the transparent electrodes and polarization of light irradiated from the backlight. By changing the state, an image or the like is displayed.

On the other hand, when distortion exists in glass, it is known that the light transmitted will generate birefringence by the distortion. That is, when distortion exists in the glass substrate for a display in the liquid crystal display, polarization elements other than the alignment of the liquid crystal are added, and the polarization state cannot be controlled only by the application of the voltage between the transparent electrodes. As a result, display nonuniformity arises in a liquid crystal display, and it becomes the cause of the fall of liquid crystal display quality. In addition, the recent large screen of liquid crystal displays has brought about the problem of luminance unevenness. Especially, if there is distortion in the glass substrate for display, the light of the backlight leaking from the polarizing plate uniformly when black is displayed on the front surface of the liquid crystal display is uniform. Since it disappears, the said luminance nonuniformity is remarkable. Thus, although the brightness nonuniformity generate | occur | produces in a liquid crystal display becomes a big problem, it is time and cost to evaluate the brightness nonuniformity after assembling a liquid crystal panel, and it is necessary to evaluate brightness nonuniformity in the state of a glass substrate.

As an apparatus for detecting the distortion of a glass plate, the following patent document 1 proposes the photoelastic device which consists of two polarizing plate (polarizer and an analyzer) samples orthogonal to each other. When observing the glass plate on the sample stage in the state in which the main axes of the two polarizing plates are orthogonal to each other, the distorted image is observed when distortion is present in the glass plate. The dark part in this distortion image corresponds to the part where the main stress of the glass plate coincides with the direction of the main axis of the polarizing plate so that the glass plate on the sample table is rotated with respect to the polarizing plate or the polarizer plate is rotated with respect to the glass plate on the sample bed. The main stress line of the glass plate can be obtained by observing.

However, in the method described in Patent Document 1 below, since the glass plate on the sample stage, one polarizing plate (polarizer) and the other polarizing plate (analyzer) are arranged in a state separated from each other, the scattered light at the surface of these members is different. It cannot pass through the polarizing plate (analyzer) of a side, and the distortion of favorable contrast cannot be obtained. Therefore, although the main stress line (direction of main stress) of a glass plate can be calculated | required by the method of following patent document 1, it is related to the distorted direction which is not constant like luminance unevenness, and the delicate quality which is also influenced by the slight distortion It cannot be evaluated quickly and accurately.

In Patent Document 2 below, in order to provide a glass substrate for display that suppresses the deflection at the time of conveyance and thermal warping due to heat treatment, the deviation stress at multiple points of one glass substrate at predetermined intervals is converted from the optical path difference of birefringence. The purpose of measuring distortion is described.

However, in this method, since it is necessary to measure multiple points of deviation stresses of one glass substrate, much time is required for evaluating one glass substrate, and rapid evaluation cannot be performed in a short time. In addition, since the deviation stress is measured for every zone of one glass substrate, evaluation of the whole glass substrate cannot be performed at once.

As described above, the measurement of the distortion of the glass substrate in order to evaluate the shape quality such as the deflection or warpage of the glass plate has been conventionally performed, but the degree of luminance non-uniformity generated in the glass substrate in the state of the glass substrate before assembling as a display panel. Evaluating was not done.

Japanese Patent Laid-Open No. 55-58428 Japanese Patent Laid-Open No. 2001-180957

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art as described above, and a method capable of quickly and accurately evaluating the luminance non-uniformity generated in the glass substrate in the state of the glass substrate before assembling as a display panel at low cost. It is an object of the present invention to provide a method for producing a glass substrate for a glass and a glass substrate for a display that can prevent occurrence of luminance unevenness.

The invention according to claim 1 comprises inserting a glass substrate for a display between a first polarizing plate arranged in a direction in which light is irradiated from a light source and a second polarizing plate arranged to be orthogonal to the polarization axis of the first polarizing plate, wherein A luminance non-uniformity evaluation method of a display glass substrate for evaluating luminance non-uniformity by detecting light passing through the polarizing plate, the display glass substrate, and the second polarizing plate, wherein the display glass substrate is used as the first polarizing plate and the second Surface contact with a polarizing plate relates to a luminance non-uniformity evaluation method of a glass substrate for a display. Preferably, it is comprised so that the said glass substrate, a 1st polarizing plate, and a 2nd polarizing plate may surface-contact in the area | region (luminance nonuniformity evaluation range) or more of the area of the glass substrate for display which brightness unevenness should be evaluated.

The invention according to claim 2 relates to a method for evaluating luminance non-uniformity of the glass substrate for display according to claim 1, wherein the light source and the first polarizing plate are in contact with each other.

The invention according to claim 3 relates to a luminance non-uniformity evaluation method of the glass substrate for display according to claim 1 or 2, wherein the luminance of the light source is 8000 cd / m 2 or more.

The invention according to claim 4 relates to a method for evaluating the luminance non-uniformity of the glass substrate for display according to any one of claims 1 to 3, wherein the plate thickness of the glass substrate for display is 0.01 mm to 1.1 mm.

The invention according to claim 5 relates to a method for evaluating luminance non-uniformity of the glass substrate for display according to any one of claims 1 to 4, wherein the length of one side of the glass substrate for display is 900 mm or more.

The invention according to claim 6 is evaluated from a position having a 10 ° to 80 ° viewing angle from the second polarizing plate, and relates to a method for evaluating luminance non-uniformity of the glass substrate for display according to any one of claims 1 to 5. .

The invention according to claim 7 is provided with the first polarizing plate, the second polarizing plate, and the display glass substrate standing up, wherein the luminance non-uniformity evaluation of the glass substrate for display according to any one of claims 1 to 6 is characterized by the above-mentioned. It is about a method.

The invention according to claim 8 relates to a method for evaluating the luminance non-uniformity of the glass substrate for display according to any one of claims 1 to 7, which is evaluated from a position separated from the second polarizing plate by 2 to 6 m.

The invention according to claim 9 relates to a method for evaluating luminance non-uniformity of the glass substrate for display according to any one of claims 1 to 8, wherein the display glass substrate is a glass substrate for a liquid crystal display.

The invention according to claim 10 relates to a method for evaluating luminance non-uniformity of the glass substrate for display according to claim 9, wherein the light source is a backlight unit for a liquid crystal display.

The invention according to claim 11 is a first step of producing a glass substrate for display by cutting an edge portion after cutting a predetermined length while conveying a glass ribbon after molding, and a first polarizing plate arranged in a direction in which light is irradiated from a light source. A second step of inserting the glass substrate for display produced in the first step between the second polarizing plates arranged so as to be orthogonal to the polarization axis of the first polarizing plate, and then surface contacting the first polarizing plate and the display from the light source; And a third step of detecting luminance non-uniformity by detecting light passing through the second polarizing plate, and a fourth step of selecting the evaluated glass substrate for display as good or defective. It relates to a method for producing a glass substrate for use.

The invention according to claim 12 relates to a glass substrate for display manufactured by the manufacturing method according to claim 11.

Effect of the Invention

According to the invention according to claim 1, since the glass substrate for display is brought into surface contact with the first polarizing plate and the second polarizing plate, it is difficult to be influenced by the scattered light on the surface of these members and an image with good contrast can be obtained. Therefore, the luminance nonuniformity generated in the glass substrate in the state of the glass substrate before assembling as the display panel can be evaluated quickly and accurately at low cost. In particular, the glass substrate, the first polarizing plate, and the second polarizing plate are in surface contact with each other in a range of a region (luminance non-uniformity evaluation range) of the display glass substrate for which luminance unevenness is to be evaluated, thereby limiting the luminance nonuniformity evaluation range of the glass substrate. Inspection can be done at a time, which reduces the time required for inspection. In addition, the luminance unevenness may be caused by a member other than the glass substrate for display (for example, a backlight unit or a deflection plate), but more precisely than when the display panel is actually assembled by using the method of the present invention. It becomes possible to evaluate the luminance nonuniformity resulting from a glass substrate.

According to the invention according to claim 2, since the light source and the first polarizing plate are in contact with each other, the position of the light source and the first polarizing plate is the same as when the display panel is assembled. The luminance nonuniformity can be evaluated, and the luminance nonuniformity of the glass substrate for a display can be evaluated more correctly.

According to invention of Claim 3, since the brightness | luminance of a light source is 8000 cd / m <2> or more, the part which light transmits from a orthogonal polarizing plate is emphasized more brightly, and the brightness nonuniformity of a glass substrate for a display can be evaluated more quickly and accurately. .

According to the invention according to claim 4, since the plate thickness of the glass substrate for a display is 0.01 mm-1.1 mm, since it becomes conditions of the same thickness as the thickness of the glass substrate used for a display, it displays in a state closer to the state which created the display panel. The luminance nonuniformity of a glass substrate for evaluation can be evaluated, and the luminance nonuniformity of a glass substrate for a display can be evaluated more accurately.

According to invention of Claim 5, since the length of one side of a glass substrate for a display is 900 mm or more, the luminance nonuniformity of the display glass substrate used for the large size display which a brightness nonuniformity tends to generate | occur | produce can be evaluated more quickly and accurately.

According to the invention according to claim 6, since the evaluation is performed from a position having a viewing angle of 10 ° to 80 ° from the second polarizing plate, the contrast of the evaluation surface does not change, and the average brightness is improved, so that the luminance non-uniformity can be easily visually evaluated. .

According to invention of Claim 7, since the 1st polarizing plate, the 2nd polarizing plate, and the glass substrate for a display are provided upright, the luminance nonuniformity of a glass substrate for a display can be evaluated more correctly.

According to the invention according to claim 8, it is easy to confirm the luminance non-uniformity of the glass substrate for display because it is evaluated from a position 2 to 6 m apart from the second polarizing plate, and more accurately from the distance at which a user actually watches a thin television. The luminance nonuniformity of can be evaluated.

According to invention of Claim 9, since the glass substrate for a display is a glass substrate for liquid crystal displays, the luminance nonuniformity of the glass substrate for liquid crystal displays used for the liquid crystal display which a brightness nonuniformity tends to produce more easily can be evaluated.

According to the invention according to claim 10, since the light source is the backlight unit for the liquid crystal display, since the same light source as the light source used for the liquid crystal display is used, the luminance non-uniformity of the glass substrate for the liquid crystal display can be evaluated in a state closer to that of the liquid crystal display panel. The luminance nonuniformity of the glass substrate for a display can be evaluated more correctly.

According to invention of Claim 11, the 1st process of manufacturing the glass substrate for a display by cutting an edge part after cutting to a predetermined length, conveying a glass ribbon after molding, and the 1st polarizing plate arrange | positioned in the direction to which light is irradiated from a light source And a second step of inserting the glass substrate for display produced in the first step between the second polarizing plate arranged so as to be orthogonal to the polarization axis of the first polarizing plate and then surface contacting the first polarizing plate and the glass substrate for display. And a third step of detecting the luminance non-uniformity by detecting the light passing through the second polarizing plate and a fourth process of selecting the evaluated glass substrate for display as good or defective, so that the luminance non-uniformity when assembled to the display panel The glass substrate for a display which makes it possible to prevent the occurrence of can be produced.

According to invention of Claim 12, since it is a glass substrate for displays manufactured by the manufacturing method of Claim 11, when it is assembled to a display panel, it can be set as the display glass substrate which makes it possible to prevent generation | occurrence | production of a luminance nonuniformity.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic block diagram of the brightness nonuniformity evaluation method of the glass substrate for a display by this invention.
It is a detail view of the polarizing plate used by the brightness nonuniformity evaluation method of the glass substrate for a display by this invention.
It is explanatory drawing which shows the state which is actually evaluating a brightness nonuniformity by the brightness nonuniformity evaluation method of the glass substrate for a display by this invention.
It is explanatory drawing which shows another embodiment of the brightness nonuniformity evaluation method of the glass substrate for a display by this invention.
It is a figure which shows an example of the shaping | molding method used for the glass substrate for a display by this invention.

EMBODIMENT OF THE INVENTION Hereinafter, preferred embodiment of the brightness nonuniformity evaluation method of the glass substrate for a display by this invention is described, referring drawings.

In the brightness non-uniformity evaluation method of the glass substrate for a display by this invention, the 1st polarizing plate 2 arrange | positioned in the direction to which light is irradiated from the light source 1, and the 2nd arrange | positioned so as to orthogonal to the polarization axis of the 1st polarizing plate 2 The glass substrate 4 for a display is inserted between the polarizing plates 3, and the surface contact of the 1st polarizing plate 2 and the glass substrate 4 for display, and the 2nd polarizing plate 3 and the glass substrate 4 for display is carried out. It is characterized by that.

Here, "surface contact" means that the glass substrate for display, the first polarizing plate, and the second polarizing plate are not only in contact with each other uniformly in all parts but also partially apart, that is, the surfaces are substantially in contact with each other. It is included if present.

The kind of the light source 1 is not specifically limited, A fluorescent lamp, an incandescent bulb, a light emitting diode, etc. can be used. Although the number of arrangement | positioning of the light source 1 is suitably selected according to the kind of light source 1, the number which can irradiate at least the whole surface of a 1st polarizing plate uniformly is needed. Although it does not specifically limit about light color, It is preferable to use light color. This is because the first polarizing plate 2 and the second polarizing plate 3 are orthogonal to each other, so that when a dark color is used, there is a possibility that almost no light can be detected by the naked eye. Usually, white light is used.

It is preferable that it is 8000 cd / m <2> or more, and, as for the brightness | luminance of the light source 1, it is more preferable that it is 10000 cd / m <2> or more. This is because the point where light transmits from the orthogonal polarizing plate is emphasized more brightly, and therefore, the luminance non-uniformity of the glass substrate for display can be evaluated more quickly and accurately.

As shown in FIG. 2, the light source 1 is preferably arranged to be in contact with the first polarizing plate 2. It is because the luminance nonuniformity of the glass substrate for a display can be evaluated in the state closer to the state which created the display panel, and the luminance nonuniformity of the glass substrate for a display can be evaluated more correctly.

The first polarizing plate 2 is a planar body having a substantially rectangular shape as viewed in a plane. As shown in FIG. 2, the first polarizing plate 2 is made of a polarizing film 21 and a plate-like transparent body 22, and a polarizing film on the plate-like transparent body 22. It is comprised by sticking (21). It is preferable that the magnitude | size of the 1st polarizing plate 2 is more than the magnitude | size of the glass substrate 4 for displays which evaluates a brightness nonuniformity, and it is at least that the polarizing film 21 is more than the brightness nonuniformity evaluation range of the glass substrate 4 for displays. need. The 1st polarizing plate 2 is arrange | positioned so that the plate-shaped transparent body 22 may be a light source 1 side, and the polarizing film 21 may be a glass substrate 4 for a display side. This is for evaluating only the luminance nonuniformity by the glass substrate 4 for a display, without being influenced by the distortion which the plate-shaped transparent body 22 has.

The plate-like transparent body 22 needs to be made of a material that is hard to be distorted due to its high rigidity, and plate glass, hard plastic, or the like can be used. The plate thickness of the plate-shaped transparent body 22 is appropriately selected depending on the rigidity of the material to be selected, but preferably has a plate thickness that is not distorted at least when using the evaluation method according to the present invention. For example, when plate glass is selected as the material, the plate thickness is preferably 0.5 mm or more. The plate-shaped transparent body 22 needs the size of at least the polarizing film 21 or more.

The second polarizing plate 3 is formed of a polarizing film 31 and a plate-like transparent body 32 as the first polarizing plate 2, as shown in FIG. It is comprised by sticking the polarizing film 31 to the transparent body 32. FIG. The size of the second polarizing plate 3 is the same as that of the first polarizing plate 2 and is usually the same as the first polarizing plate 2. The second polarizing plate 3 is disposed such that the polarizing film 31 is on the glass substrate 4 side for display.

As the glass substrate 4 for display, silicate glass is used, Preferably silica glass and borosilicate glass are used, Most preferably, alkali free borosilicate glass is used. If the alkali component is contained in the display glass substrate 4, there exists a possibility that an alkali component may elute and a TFT may be damaged. In addition, an alkali free borosilicate glass is glass which does not contain an alkali component substantially here, specifically, it is glass whose alkali component is 1000 ppm or less. Content of the alkali component in this invention, Preferably, an alkali component is 500 ppm or less, More preferably, an alkali component is 300 ppm or less.

The glass substrate 4 for a display is a plate-shaped object of substantially rectangular shape viewed from a plane, and it is preferable that plate | board thickness is 0.01 mm-1.1 mm. It is because when it is too thin than 0.01 mm, it is easy to be influenced by the internal distortion by the interference of light, the distortion of the glass substrate for evaluation objects display, etc., and when too thick than 1.1 mm, the brightness | luminance at the time of evaluation will fall. More preferable plate | board thickness is 0.1 mm-0.7 mm, More preferable plate | board thickness is 0.1 mm-0.5 mm.

It is preferable that the length of one side of the glass substrate 4 for a display is 900 mm or more. It is because the luminance nonuniformity of the glass substrate used for the large size display which a luminance nonuniformity tends to generate | occur | produce can be evaluated.

The glass substrate 4 for a display used for this invention can be shape | molded by a well-known method, such as a roll out method, the float method, the slit down method, the overflow down draw method. Especially, it is preferable to shape | mold by the overflow downdraw method. The overflow downdraw method is a molding method in which both surfaces of the glass plate do not come into contact with the molding member at the time of molding, and damage is unlikely to occur on both surfaces (transmission surface) of the obtained glass film, and thus high surface quality can be obtained without polishing.

In the evaluation method of the glass substrate for a display by this invention, the 1st polarizing plate 2 and the glass substrate 4 for displays, and the 2nd polarizing plate 3 and the glass substrate 4 for displays are surface-contacted. If these are separated, scattered light from the surfaces of the first polarizing plate 2, the display glass substrate 4, and the second polarizing plate 3 passes through the second polarizing plate 3, and the contrast of the evaluation surface is lowered. The luminance nonuniformity evaluation of the glass substrate for a display cannot be performed quickly and correctly. In the present invention, since such scattered light can be removed by surface contact, luminance non-uniformity evaluation of the glass substrate for display can be performed quickly and accurately.

In the evaluation method of the glass substrate for a display by this invention, as shown in FIG. 3, the evaluation position is not the front surface of the 2nd polarizing plate 3, but rather from the direction which has a viewing angle to some extent in an up-down direction and a left-right direction. It is preferable to evaluate the luminance nonuniformity of the board | substrate 4. It is difficult to evaluate the luminance nonuniformity directly from the front surface of the second polarizing plate 3, and the contrast angle of the evaluation surface does not change and the average brightness is the one having the viewing angle with respect to the light source 1 (the evaluation performed from the inclination). It is because it becomes easy to evaluate a brightness nonuniformity visually because it improves. It is preferable to evaluate from the direction which has a viewing angle of 10 degrees-80 degrees in an up-down direction and a left-right direction, and it is more preferable to evaluate from the direction which has a viewing angle of 30 degrees-60 degrees.

In the evaluation method of the glass substrate for a display by this invention, when there exists reflected light from the surroundings, it becomes difficult to evaluate appropriate luminance nonuniformity, It is preferable that it is a dark place, and, as for the evaluation environment, it is more preferable that it is a dark room.

In the evaluation method of the glass substrate for a display by this invention, it is preferable that the 1st polarizing plate 2, the 2nd polarizing plate 3, and the glass substrate 4 for a display stand upright. Evaluation of the luminance nonuniformity of the glass substrate 4 for a display is difficult to judge from the position near, and since the position which was separated can be performed more correctly, the 1st polarizing plate 2, the 2nd polarizing plate 3, and the glass for display It is because the one where the board | substrate 4 is installed upright can determine the luminance nonuniformity of the glass substrate 4 for a display from the position which was farther than when it mounted horizontally, as shown in FIG.

In addition, in the evaluation method of the glass substrate for a display by this invention, as shown in FIG. 4, the light source 1, the 1st polarizing plate 2, the display glass substrate 4, and the 2nd polarizing plate 3 are sequentially Lamination | stacking may be carried out so that it may be laminated horizontally, and brightness nonuniformity evaluation may be performed from the upper direction at intervals from the 2nd polarizing plate 3. When the method of the said form is used, the 1st polarizing plate 2, the glass substrate 4 for displays, and the 2nd polarizing plate 3 can be prevented more reliably by gravity, an external force, etc.

In the evaluation method of the glass substrate for a display by this invention, it is preferable to evaluate from the position spaced 2-6 m from the 2nd polarizing plate 3. It is because the luminance nonuniformity of the glass substrate 4 for a display is easy to confirm, and the luminance nonuniformity of the glass substrate 4 for display can be evaluated more accurately from the distance with which a user actually watches a thin television. The light leakage due to the viewing angle increases when the distance is closer to 2m, and when the distance is greater than 6m, it is difficult to evaluate visually depending on the visual acuity of the evaluator 5. In any case, the luminance of the glass substrate 4 for display is increased. It is not preferable because the unevenness becomes difficult to see.

It is preferable that the glass substrate 4 for a display is a glass substrate for liquid crystal displays. It is because the brightness nonuniformity of the glass substrate used for the liquid crystal display which a brightness nonuniformity tends to generate more can be evaluated.

In addition, it is preferable that the light source 1 uses the backlight unit for liquid crystals. By using the same light source and the same glass substrate as those used in the liquid crystal display, the luminance nonuniformity of the glass substrate for display can be evaluated more closely in the state where the liquid crystal panel was prepared, and the luminance nonuniformity of the glass substrate for display can be evaluated more accurately. Because there is. For example, a liquid crystal backlight unit in which a plurality of fluorescent lamps or white diodes of a cold cathode ray tube are arranged is preferably used.

Although the evaluation method of the glass substrate for a display by this invention demonstrated the form which an evaluator performs with visual observation, the brightness is measured and analyzed by using image processing apparatuses, such as a well-known CCD camera, It is also possible to make the determination mechanically.

The evaluation method of the glass substrate 4 for displays by this invention can be performed also in any form of water irradiation and extraction irradiation. In the case of performing all-in-one irradiation, the display glass substrate 4 judged to be good after evaluation is polished on both sides of the substrate, and then washed, dried and packed. In the case of the glass substrate 4 for a display shape | molded by the float method, since a grinding | polishing process is needed, it is preferable to carry out whole irradiation. On the other hand, in the case of the glass substrate for a display shape | molded by the overflow down-draw method, since a grinding | polishing process is not needed, it is preferable to perform extraction irradiation. Extraction irradiation removes a predetermined number of display glass substrates 4 from a manufacturing line every predetermined period, and determines the good goods using the evaluation method of the glass substrate 4 for displays by this invention. Regarding the glass substrate 4 for display used directly for evaluation by judging the state of the luminance non-uniformity for each lot by extraction irradiation, it is re-melted and remolded without being used as a product, whether a good or bad product.

It is a figure which shows an example of the shaping | molding method used for the glass substrate for a display by this invention.

The glass substrate for a display by this invention can be manufactured with the following manufacturing methods.

The glass ribbon G immediately after falling from the lower end portion 61 of the shaped body 6 having a wedge cross section is stretched downward while being restricted in the width direction by the cooling roller 7 to be thinned to a predetermined thickness. . Subsequently, the glass ribbon G that reached the predetermined thickness was gradually cooled in a slow cooling furnace (annealer) to remove thermal distortion of the glass ribbon G, and the glass ribbon G was cut to a predetermined dimension. After that, the edge portion is cut to form the glass substrate 4 for display. About cutting | disconnection of glass ribbon G, you may cut | disconnect end edge part first, and you may cut | disconnect to predetermined dimension after that.

The first polarizing plate 2 and the glass substrate 4 for display and the second polarizing plate 3 and the display glass substrate 4 are surface-contacted using the molded and cut glass substrate 4 for display. After that, light is irradiated to the first polarizing plate 2 from a light source such as a fluorescent lamp, and the change in the amount of light passing through the first polarizing plate 2, the glass substrate 4 for display, and the second polarizing plate 3 is performed. The luminance nonuniformity of the glass substrate 4 for a display is evaluated by observing the presence or absence of the luminance nonuniformity from the 2nd polarizing plate 4 side. It is judged to be defective when the contrast difference can be confirmed in a relatively narrow area such as a directional nonuniformity in the longitudinal and transverse oblique direction as a luminance nonuniformity, or a nonuniformity recognized as an indefinite area with different luminance from the surroundings. Limit samples are used as criteria for judgment. In the case of performing all-in-one irradiation, the glass substrate 4 for display, which has been judged as a good product, is then released after passing through processes such as processing, polishing, washing, and wrapping. About the glass substrate 4 for a display which determined with the inferior goods, it melt | dissolves and evaluates a luminance nonuniformity again after reshaping. In the case of performing extraction irradiation, when the extracted glass substrate 4 for display is judged good quality, a release operation | work is performed with respect to the other display glass substrate 4 in the said lot. The glass substrate 4 for a display used in the determination is remelted without being released. If it is judged as defective, all the display glass substrates 4 in the lot are re-melted without being released. Review of operating conditions such as melting conditions, molding conditions, and the like, the luminance non-uniformity is evaluated for every predetermined lot, and the conditions are reviewed until the display glass substrate 4 is judged to be good.

When it is assembled to a display panel by the manufacturing method mentioned above, it can be set as the glass substrate 2 for a display which makes it possible to prevent generation | occurrence | production of a luminance nonuniformity.

The present invention can be suitably used for evaluating the presence or absence of occurrence of luminance unevenness in the glass substrate for display.

1-light source 2-first polarizer
21-polarizing film 22-plate-shaped transparent body
3-2nd polarizing plate 31-polarizing film
32-plate-shaped transparent body 4-glass substrate for display
5-Evaluator 6-Molded article
7-cooling roller

Claims (12)

A glass substrate for a display is inserted between a 1st polarizing plate arrange | positioned in the direction to which light is irradiated from a light source, and a 2nd polarizing plate arrange | positioned so as to be orthogonal to the polarization axis of this 1st polarizing plate, and the said 1st polarizing plate and the said glass for display from the said light source As a luminance non-uniformity evaluation method of a glass substrate for a display which detects the board | substrate and the light which permeate | transmits the said 2nd polarizing plate and evaluates a luminance non-uniformity:
A surface non-uniformity evaluation method of the glass substrate for display, wherein the display glass substrate is brought into surface contact with the first polarizing plate and the second polarizing plate. The method of claim 1,
The light source and the first polarizing plate are in contact with each other, characterized in that the luminance non-uniformity evaluation method of the glass substrate for display. The method according to claim 1 or 2,
The brightness of the said light source is 8000 cd / m <2> or more, The brightness nonuniformity evaluation method of the glass substrate for a display characterized by the above-mentioned. The method according to any one of claims 1 to 3,
The plate | board thickness of the said glass substrate for displays is 0.01 mm-1.1 mm, The brightness nonuniformity evaluation method of the glass substrate for displays characterized by the above-mentioned. The method according to any one of claims 1 to 4,
The length of one side of the said glass substrate for displays is 900 mm or more, The brightness nonuniformity evaluation method of the glass substrate for displays characterized by the above-mentioned. 6. The method according to any one of claims 1 to 5,
It evaluates from the position which has a viewing angle of 10 degrees-80 degrees from a said 2nd polarizing plate, The brightness nonuniformity evaluation method of the glass substrate for a display characterized by the above-mentioned. The method according to any one of claims 1 to 6,
The said 1st polarizing plate, the said 2nd polarizing plate, and the said glass substrate for a display are provided upright, The brightness nonuniformity evaluation method of the glass substrate for display characterized by the above-mentioned. The method according to any one of claims 1 to 7,
It evaluates from the position separated by 2-6m from the said 2nd polarizing plate, The brightness nonuniformity evaluation method of the glass substrate for a display characterized by the above-mentioned. The method according to any one of claims 1 to 8,
The said glass substrate for displays is a glass substrate for liquid crystal displays, The brightness nonuniformity evaluation method of the glass substrate for displays characterized by the above-mentioned. The method of claim 9,
The light source is a backlight unit for a liquid crystal display, characterized in that the luminance non-uniformity evaluation method of the glass substrate for display. 1st process of manufacturing the glass substrate for a display by cutting an edge part after cutting out to predetermined length, conveying a glass ribbon after molding;
After inserting the glass substrate for display produced in the first step between the first polarizing plate arranged in the direction from which the light is irradiated from the light source and the second polarizing plate arranged to be orthogonal to the polarization axis of the first polarizing plate, the surface contact is performed. Second process;
A third step of detecting the lightness non-uniformity by detecting the light passing through the first polarizing plate, the display glass substrate, and the second polarizing plate from the light source; And
It has a 4th process which sorts the evaluated glass substrate for a display into good and defective products, The manufacturing method of the glass substrate for a display characterized by the above-mentioned. It is manufactured by the manufacturing method of the glass substrate for displays of Claim 11, The glass substrate for displays characterized by the above-mentioned.

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