JP2003121857A - Color filter for liquid crystal display device provided with columnar spacer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a color filter for a liquid crystal display device provided with columnar spacers, with which the liquid crystal display device can be attained, wherein panel assembly can be performed while the gap is being properly maintained, the gap is reduced and fixedly maintained when excess load is applied or when a liquid crystal is contracted under a low temperature condition and accordingly color unevenness or the like is not generated and vacuum bubbles (low temperature bubbles) are not generated. SOLUTION: The columnar spacers are constituted of two columnar spacers of a columnar spacer (a first columnar spacer) having the height and the sectional area corresponding to the deformation by the load at the time when the panel is assembled and the deformation following the contraction of the liquid crystal at low temperature and a columnar spacer (a second columnar spacer) having height and sectional area holding the gap between substrates when excess load is applied and when the liquid crystal is contracted under low temperature condition.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color filter used in a liquid crystal display device, and more particularly to a color filter for a liquid crystal display device provided with a columnar spacer having a spacer function.

[0002]

2. Description of the Related Art In the conventional technology of liquid crystal display devices,
In order to form a gap between the substrates, glass or synthetic resin transparent spherical particles (beads) called spacers are dispersed. Since this spacer is a transparent particle, if there is a spacer in the pixel along with the liquid crystal, light will leak through the spacer when displaying black, and also between the substrates in which the liquid crystal material is enclosed. Due to the presence of the spacers, the alignment of the liquid crystal molecules near the spacers is disturbed, light leakage occurs at this portion, the contrast is lowered, and the display quality is adversely affected.

As a technique for solving such a problem, for example, a photosensitive resin is used, and a projection having a spacer function is formed at a position of a light shielding layer between pixels by a photofabrication method of partial pattern exposure to development. The method of doing is proposed. FIG. 1 is a partial cross-sectional view of a color filter for a liquid crystal display device showing such an example. In FIG. 1, a color filter (10) for a liquid crystal display device has a light-shielding layer (12), a pixel-like color filter layer (13), and a transparent conductive film (14) formed on a transparent substrate (11). Conductive film (1) between the color filter layers (13)
4) A columnar spacer (15) as a projection having a spacer function is formed on the surface. A large number of such columnar spacers (15) having the same horizontal cross-sectional area and the same height are formed in the plane.

FIG. 2 is a partial sectional view of a liquid crystal display device showing an example in which such a color filter (10) for a liquid crystal display device is used in a liquid crystal display device. In FIG. 2, a liquid crystal display device (50) is a liquid crystal display device color filter (1
0) and, for example, a transparent conductive film (2) on the transparent substrate (21).
The counter substrate (20) on which 4) is formed is bonded and configured. Such a liquid crystal display device (5
In 0), since the columnar spacers (15) are formed at positions avoiding the inside of the pixel, the above-mentioned contrast is improved and the impact resistance of the liquid crystal display device is improved.

In a panel assembling process in which a color filter (10) for a liquid crystal display device and a counter substrate (20) are attached to each other to form a panel, a seal portion (not shown) is provided in a peripheral portion, and a color filter (for a liquid crystal display device) is provided. The gap between the counter substrate (20) and the counter substrate (20) is made as parallel as possible, and a load is applied between the upper and lower surface plates to bond the seal portion and the columnar spacer by pressure bonding, and the columnar spacer (15) is applied by the load applied at this time. Is deformed, the gap between the substrates is set in the deformed state.

In the plane, the columnar spacers (15) are
When the columnar spacers (1
If the cross-sectional area of 5) is small, it is difficult for the gap between the substrates to be uniform in the panel assembly process, and color unevenness or the like is likely to occur in the liquid crystal display device. That is, the columnar spacer (1
The cross-sectional area of 5) should be larger than a certain size. Moreover, when an excessive load is locally applied, color unevenness or the like is likely to occur in the liquid crystal display device. On the other hand, if the cross-sectional area of the columnar spacer (15) is large, the gap between the substrates will be uniform in the panel assembly process, but vacuum bubbles will easily occur in the liquid crystal cell.

This is because the environment when the liquid crystal display device is used is
For example, in a low temperature environment such as −20 ° C., all the members constituting the liquid crystal cell tend to shrink. Since the liquid crystal has the highest shrinkage ratio among the constituent members, it tends to shrink in the direction of reducing the gap between the substrates. At this time, if the deformation of the columnar spacer cannot follow the amount of change that the gap between the substrates is trying to shrink, a negative pressure is generated inside the liquid crystal cell, and as a result, vacuum bubbles (low temperature bubbles) are generated inside the liquid crystal cell. It will be easier to do.

[0008]

According to the present invention, when a color filter for a liquid crystal display device provided with a columnar spacer is used in a liquid crystal display device, the color filter for a liquid crystal display device and a counter substrate are not bonded together. It is possible to obtain a liquid crystal display device that does not cause color unevenness by assembling the panel while properly maintaining the gap between the substrates, and also when locally applying an excessive load or at a low temperature. When the liquid crystal contracts under the environment, the gap between the substrates is reduced and the gap is kept constant, so that color unevenness does not occur and vacuum bubbles (low temperature bubbles) are generated in the liquid crystal cell. An object of the present invention is to provide a color filter for a liquid crystal display device, which is provided with a columnar spacer that can be used as a liquid crystal display device without the above.

[0009]

According to the present invention, in a color filter for a liquid crystal display device provided with a columnar spacer, the columnar spacer is prevented from being deformed by a load at the time of assembling the panel and being deformed following the contraction of the liquid crystal in a low temperature environment. Columnar spacers (first columnar spacers) with corresponding heights and cross-sectional areas, and heights and cross-sectional areas that maintain the gap between the substrates when locally overloaded and when the liquid crystal contracts in a low temperature environment It is composed of two types of columnar spacers (second columnar spacers), which keeps the gap between the substrates properly during panel assembly, and locally receives an excessive load, or under a low temperature environment. Is a color filter for a liquid crystal display device provided with a columnar spacer, characterized in that the liquid crystal is deformed when contracted to keep the gap between the substrates constant.

Further, according to the present invention, in a color filter for a liquid crystal display device having a columnar spacer, the columnar spacer has a height corresponding to the deformation due to a load during panel assembly and the deformation following the contraction of liquid crystal in a low temperature environment. , The height of the columnar spacer having the cross-sectional area (first columnar spacer) and the reference height for properly obtaining the gap between the substrates when assembling the panel, and also corresponding to the deformation following the contraction of the liquid crystal in a low temperature environment The columnar spacers (second columnar spacers) that have the same height and cross-sectional area, and the height and disconnection that keep the gap between the substrates constant when locally overloaded and when the liquid crystal contracts in a low temperature environment. It is composed of three types of columnar spacers, which have an area (third columnar spacer), and maintains a proper gap between substrates during panel assembly, When subjected to locally excessive load One,
Alternatively, it is a color filter for a liquid crystal display device provided with a columnar spacer characterized in that the liquid crystal is deformed when contracted in a low temperature environment to keep the gap between the substrates constant.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION A color filter for a liquid crystal display device provided with a columnar spacer according to the present invention will be described below based on its embodiments. FIG. 3 is a sectional view schematically showing a color filter for a liquid crystal display device provided with a columnar spacer according to the present invention. As shown in FIG. 3, a color filter for liquid crystal display (30) provided with a columnar spacer according to the present invention is a transparent substrate (31) on which a light shielding layer (not shown), a pixel color filter layer, and a transparent conductive film are formed. Columnar spacers (35) are formed on the transparent conductive film between the pixel-shaped color filter layers.

The columnar spacer (35) is composed of a first columnar spacer (32) and a second columnar spacer (33). The first columnar spacer (32) is a columnar spacer having a height and a cross-sectional area corresponding to the deformation due to the load at the time of assembling the panel and the deformation following the contraction of the liquid crystal under the low temperature environment. In addition, the second columnar spacer (33) is
It is a columnar spacer having a height and a cross-sectional area for maintaining a gap between the substrates when an excessive load is locally applied and the liquid crystal shrinks in a low temperature environment.

The height of the first columnar spacer (32) is 0.2 μm to the height of the second columnar spacer (33).
The cross-sectional area is about 0.3 μm higher and the cross-sectional area is smaller than the cross-sectional area of the second columnar spacer (33), which is about 25 μm 2 to 200 μm 2. The first columnar spacer (32) is deformed by the load when assembling the panel. The height of the second columnar spacer (33) is very slightly smaller than the gap width between the substrates desired for the liquid crystal display device, and the cross-sectional area thereof is 1000 μm 2 -10,000 μm.
It is about m2. This second columnar spacer (3
3) does not deform due to the load during panel assembly.

FIG. 4 shows a color filter (30) for a liquid crystal display device and a counter substrate (4) in a panel assembling process.
0) is attached and a panel is assembled by applying a load. Further, FIG. 5 shows that the gap between the substrate of the liquid crystal display color filter (30) and the counter substrate (40) is reduced when an excessive load is locally applied during the panel assembly or in a low temperature environment. It shows the state.

The color filter (30) for a liquid crystal display device according to the present invention has a columnar spacer (35) composed of a first columnar spacer (32) and a second columnar spacer (33), and has a cross-sectional area at the time of panel assembly. The first columnar spacers (32) having a small height are from the initial height (h1) to the height (h) of the second columnar spacers (33) depending on the load.
It is deformed to a height very close to 3) (deformed height h2). At this time, even if an excessive load is locally applied, the deformation of the first columnar spacers (32) stops at the height (h3) of the second columnar spacers (33), and the first columnar spacers (32) are not further deformed by the load.

Also, in a low temperature environment, the gap between the substrates is regulated and kept constant by the second columnar spacer (33) which is difficult to deform. Therefore, as the columnar spacer, an appropriate deformation required during panel assembly can be obtained, the gap between the substrates can be maintained at an appropriate height (width) (h2), and when an excessive load is locally applied, or A constant gap (width) between substrates even in a low temperature environment
It can be kept at (h3).

On the other hand, FIG. 6 is a sectional view schematically showing a color filter for a liquid crystal display device provided with a columnar spacer according to claim 2 of the present invention. As shown in FIG. 6, a color filter (60) for a liquid crystal display device having a columnar spacer according to the present invention is a transparent substrate (61) on which a light shielding layer (not shown), a pixel color filter layer, and a transparent conductive film are formed. Columnar spacers (65) are formed on the transparent conductive film between the pixel color filter layers.

The columnar spacers (65) are the first columnar spacers (62) and the second columnar spacers (63).
And a third columnar spacer (64). The first columnar spacer (62) is a columnar spacer having a height and a cross-sectional area corresponding to the deformation due to the load at the time of assembling the panel and the deformation following the contraction of the liquid crystal under the low temperature environment.
The second columnar spacer (63) has a height that serves as a reference for properly obtaining the gap between the substrates when assembling the panel, and a height and a cross-sectional area corresponding to the deformation that follows the contraction of the liquid crystal in a low temperature environment. It is a columnar spacer having. Further, the third columnar spacer (64) is a columnar spacer having a height and a cross-sectional area for keeping the gap between the substrates constant when an excessive load is locally applied and the liquid crystal is contracted in a low temperature environment. .

The height of the first columnar spacer (62) is 0.2 μm to the height of the third columnar spacer (64).
The cross-sectional area is about 0.3 μm higher and the cross-sectional area is smaller than the cross-sectional area of the second columnar spacer (63), which is about 25 μm 2 to 200 μm 2. The first columnar spacer (62) is deformed by the load when assembling the panel. The height of the second columnar spacer (63) means that it is higher than the height of the third columnar spacer (64) by about 0.03 μm, and the cross-sectional area thereof is the cross section of the third columnar spacer (64). Means smaller than the area, 500 μm 2 to 3000 μm 2
It is of a degree. The second columnar spacer (63) is not deformed by the load when assembling the panel. But,
It deforms when it receives an excessive load locally or in a low temperature environment. The height of the third columnar spacer (64) is slightly smaller than the gap width between the substrates desired for the liquid crystal display device, and the cross-sectional area thereof is 10 mm.
It is about 100 μm 2 to 10,000 μm 2. The third columnar spacer (64) is not deformed by the load when assembling the panel.

FIG. 7 shows a color filter (60) for a liquid crystal display device and a counter substrate (8) in a panel assembling process.
0) is attached and a panel is assembled by applying a load. FIG. 8 shows that the gap between the liquid crystal display color filter (60) and the counter substrate (80) is reduced when an excessive load is locally applied during panel assembly or in a low temperature environment. It shows the state.

In the color filter (60) for a liquid crystal display device according to the present invention, the columnar spacer (65) is composed of a first columnar spacer (62), a second columnar spacer (63) and a third columnar spacer (64). And the first columnar spacer (62) having a small cross-sectional area during panel assembly.
Deforms from the initial height (h4) to a height equal to the height (h5) of the second columnar spacer (63) by the load (deformed height h5). At this time, even if an excessive load is locally applied, the third columnar spacer (3
The deformation of the first columnar spacers (32) and the second columnar spacers (33) stops at the height (h3) of 4), and is not further deformed by the load.

Further, in a low temperature environment, the gap between the substrates is regulated and kept constant by the third columnar spacer (64) which is difficult to deform. That is, when assembling the panel, the counter substrate (80) contacts the second columnar spacer (63) by the load, and is regulated by the height (h5) and kept properly. Furthermore, when locally overloaded,
Alternatively, when the liquid crystal contracts in a low temperature environment, the first columnar spacers (62) and the second columnar spacers (63) are further deformed until they come into contact with the third columnar spacers (64) which are hardly deformed by the load.

Therefore, as the columnar spacer, an appropriate deformation necessary for assembling the panel can be obtained, an appropriate gap between the substrates can be obtained by the second columnar spacer (63), and an excessive load is locally applied. The gap between the substrates is constant height (width) even in low temperature environment.
It can be maintained at (h6). That is, the gap control between the substrates becomes more reliable.

The first columnar spacer (62), the second columnar spacer (63), and the third columnar spacer (6)
When 4) is formed by a photofabrication method using a photosensitive resin, for example, the heights of the first columnar spacers (62), the second columnar spacers (63), and the third columnar spacers (64) are Because of the difference, the step of forming the first columnar spacer (62) and the second columnar spacer (6)
It is to be formed in three steps including the step 3) and the step of forming the third columnar spacers (64).

However, in general, when a columnar pattern having different cross-sectional areas is formed using a negative photosensitive resin,
Even if the applied photosensitive resin has the same thickness,
A difference occurs in the height of the obtained columnar patterns. That is,
The columnar pattern having a small cross-sectional area tends to be high, and the columnar pattern having a large cross-sectional area tends to be low. It is also possible to form the three types of columnar patterns having different heights as described above in one step by utilizing the propensity of the negative type photosensitive resin. Note that it is also possible to easily form three or more types of columnar patterns in one step.

[0026]

The present invention will be described in detail below with reference to examples. <Example 1> [Preparation of photosensitive resin composition for columnar spacer] A negative type photosensitive resin composition for columnar spacer was prepared with the following composition. Acrylic resin (manufactured by Daicel Chemical Industries, Ltd., Cyclomer P-ACA200M) 100% by weight Photopolymerizable monomer Toyo Gosei Co., Ltd., Aronix M400 60 parts by weight Polymerization initiator (Ciba Specialty Chemicals, IRG907) 20 parts by weight Solvent Propylene glycol monomethyl ether acetate

[Production of Columnar Spacer] Using the above-mentioned photosensitive resin composition for columnar spacers, a photosensitive resin layer is provided on a transparent substrate on which a light shielding layer, a pixel color filter layer, and a transparent conductive film are formed. / Cm2 exposure, Na
Develop with 0.1% CO3 solution 60 seconds, 250 ℃ ・ 1
After baking for a period of time, a color filter for a liquid crystal display device having columnar spacers was obtained.

As the columnar spacers, the same number of the first columnar spacers and the second columnar spacers are arranged, and the arrangement densities in the plane are 2.85 pieces / mm 2, respectively, that is, a total of 5.
The arrangement density was 7 lines / mm 2. The height of the second columnar spacer was 4.6 μm. This 4.6 μm
Is the desired gap width value. Cross-sectional area is about 1600
μm 2 (40 × 40 μm). The height of the first columnar spacers obtained by the simultaneous formation was 4.8 μm. The cross-sectional area was about 100 μm 2 (10 × 10 μm). Table 1 shows the dimensions of the first columnar spacer and the second columnar spacer.

[0029]

[Table 1]

In the color filter for a liquid crystal display device provided with the obtained columnar spacer, 5.9 N per 1 cm 2 is provided.
When a deformation of the first columnar spacer was measured by applying a load of (0.6 kg / cm 2), a height of 4.8 μm was 4.
It was deformed to 63 μm. This 5.9 N (0.6 kg / cm
The load of 2) is 20m per 1st columnar spacer
It is a load equivalent to N. In the actual panel assembly process, a load of about 10 mN is applied to each columnar spacer. Furthermore, the load is 17.7 N (3.0 kg / cm2
), The deformation was measured, and the deformation remained at 4.6 μm.

This is because the load is supported by the second columnar spacer. That is, even if an excessive load is locally applied, there is almost no deformation and the thickness remains at 4.6 μm.
At this time, the load per first columnar spacer is
It becomes about 100 mN up to the height of 4.6 μm, and about 6 mN after the height of 4.6 μm. Further, the load per second columnar spacer is 0 mN up to a height of 4.6 μm, and the height is 4.
After 6 μm, it becomes about 94 mN.

A liquid crystal display device was manufactured using the color filter for a liquid crystal display device provided with the above-mentioned columnar spacer, and when exposed to a low temperature environment of −20 ° C., vacuum bubbles (low temperature bubbles) in the liquid crystal cell were generated. No outbreak was observed. This indicates that the first columnar spacer was deformed following the contraction of the liquid crystal at low temperature. This deformation keeps the gap constant at 4.6 μm due to the presence of the second columnar spacer, which is difficult to deform.

Comparative Example 1 The same photosensitive resin composition for columnar spacers as in Example 1 was used, and the columnar spacers were prepared in the same manner as in Example 1, and a liquid crystal display device provided with columnar spacers was used. To obtain a color filter. As the columnar spacers, only the first columnar spacers were arranged, and the arrangement density in the plane was 5.7 pieces / mm 2. The height of the first columnar spacer was 4.8 μm. The cross-sectional area was about 100 μm 2 (10 × 10 μm). Table 1 shows the dimensions of the first columnar spacer.

A color filter for a liquid crystal display device provided with the obtained columnar spacer was applied to a color filter of 5.9 N / cm 2.
When a deformation of the first columnar spacer was measured by applying a load of (0.6 kg / cm 2), a height of 4.8 μm was 4.
It was deformed to 7 μm. In addition, this 5.9 N (0.6 kg / c
The load of m2) is 10 per 1st columnar spacer.
It is a load equivalent to mN. Furthermore, the load is 17.7N
The deformation was measured by gradually adding (3.0 kg / cm 2) and the deformation reached 4.46 μm. That is,
It was shown that the gap between the substrates was not properly maintained during panel assembly.

Further, when a liquid crystal display device was manufactured using the color filter for a liquid crystal display device provided with the above-mentioned columnar spacer, color unevenness was generated and the display quality was poor. Further, when the liquid crystal display device was exposed to a low temperature environment of −20 ° C., no generation of vacuum bubbles (low temperature bubbles) was observed in the liquid crystal cell. As a result, it was shown that the first columnar spacer was deformed following the contraction of the liquid crystal at low temperature.
Color unevenness occurred in the liquid crystal display device, and the display quality was poor.

[0036]

INDUSTRIAL APPLICABILITY According to the present invention, the columnar spacer has a height and a cross-sectional area corresponding to the deformation due to the load at the time of assembling the panel and the deformation following the contraction of the liquid crystal in the low temperature environment (first columnar spacer). And two types of columnar spacers, which are columnar spacers (second columnar spacers) having a height and a cross-sectional area that maintain a gap between substrates when an excessive load is locally applied and the liquid crystal contracts in a low temperature environment. Since it is a color filter for a liquid crystal display device provided with a columnar spacer configured, when assembling the color filter for a liquid crystal display device and the counter substrate, the panel between the substrates should be properly maintained with a uniform gap. Therefore, it is possible to obtain a liquid crystal display device which does not cause color unevenness, and when the liquid crystal display device receives an excessive load locally or in a low temperature environment, When contracted, the gap between the substrates is reduced, and the gap is kept constant. Therefore, color unevenness does not occur and vacuum bubbles (low temperature bubbles) do not occur in the liquid crystal cell. It becomes a color filter for a liquid crystal display device provided with a columnar spacer which can be

Further, according to the present invention, the columnar spacer has a height and a cross-sectional area corresponding to the deformation due to the load at the time of assembling the panel and the deformation following the contraction of the liquid crystal under the low temperature environment (first columnar spacer). And a columnar spacer (a second height which is a reference height for properly obtaining the gap between the substrates during panel assembly and has a height and a cross-sectional area corresponding to the deformation following the contraction of the liquid crystal in a low temperature environment. Columnar spacers) and columnar spacers (third columnar spacers) that have a height and cross-sectional area that keep the gap between the substrates constant when an excessive load is locally applied and when the liquid crystal contracts in a low temperature environment. Since it is a color filter for a liquid crystal display device that is provided with columnar spacers, it is possible to ensure that the gaps between the substrates are properly and uniformly maintained. Performed freshly seen, therefore can be a liquid crystal display device does not cause further generate color unevenness,
In addition, when an excessive load is locally applied or when the liquid crystal is contracted in a low temperature environment, the gap between the substrates is reduced, and the gap is kept constant, so that color unevenness is more likely to occur. And a color filter for a liquid crystal display device provided with columnar spacers, which can be a liquid crystal display device in which vacuum bubbles (low temperature bubbles) are less likely to occur in the liquid crystal cell.

[Brief description of drawings]

FIG. 1 is a partial cross-sectional view of a color filter for a liquid crystal display device.

FIG. 2 is a partial cross-sectional view of a liquid crystal display device showing an example in which a color filter for a liquid crystal display device is used in the liquid crystal display device.

FIG. 3 is a cross-sectional view schematically showing a color filter for a liquid crystal display device having columnar spacers according to the present invention.

FIG. 4 is an explanatory diagram showing a state in which a color filter for a liquid crystal display device and a counter substrate are bonded together to be assembled into a panel.

FIG. 5 is an explanatory diagram showing a state in which a gap between substrates is reduced when an excessive load is locally applied or under a low temperature environment.

FIG. 6 is a cross-sectional view schematically showing a color filter for a liquid crystal display device provided with columnar spacers according to claim 2.

FIG. 7 is an explanatory diagram showing a state in which the color filter for liquid crystal display device shown in FIG. 6 and a counter substrate are attached to each other and assembled into a panel.

8 is an explanatory diagram showing a state in which the gap between the panel substrates shown in FIG. 6 is reduced when an excessive load is locally applied or in a low temperature environment.

[Explanation of symbols]

10 ... Color filters for liquid crystal display 11, 21 ... Transparent substrate 12 ... Shading layer 13 ... Pixel-like color filter layers 14, 24 ... Transparent conductive film 15 ... Column spacers 20, 40 ... Counter substrate 30, 60 ... Column according to the present invention Spacer-provided color filters 31 and 61 for liquid crystal display device ... Light-shielding layer, pixel-like color filter layer, transparent substrate 32 on which a transparent conductive film is formed ... First column spacer 33 ... Second column spacer 35 ... Column spacer 50 ... Liquid crystal display device h1 ... Initial height of first columnar spacer h2 ... Deformed height of first columnar spacer h3 ... Height of second columnar spacer h4 ... Initial height of first columnar spacer according to claim 2. h5 ... The height of the second columnar spacer according to claim 2, and the deformed height of the first columnar spacer h6 ... The third columnar space according to claim 2. Over the height, and the first columnar spacer is further deformed height, and deformed height of the second columnar spacers

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Makoto Sakakawa             1-5-1 Taito, Taito-ku, Tokyo Toppan stamp             Imprint Co., Ltd. F-term (reference) 2H089 LA09 LA12 NA48 QA14                 2H091 FA02Y FD18 GA08 LA12

Claims (2)

[Claims] 1. A color filter for a liquid crystal display device having a columnar spacer, wherein the columnar spacer has a height and a cross-sectional area corresponding to the deformation due to a load during panel assembly and the deformation following the contraction of liquid crystal in a low temperature environment. The columnar spacers (first columnar spacers) and the columnar spacers (second columnar spacers) having a height and a cross-sectional area for maintaining the gap between the substrates when locally excessive load is applied and when the liquid crystal is contracted in a low temperature environment. It is composed of two kinds of columnar spacers (spacer) and maintains a proper gap between the substrates when assembling the panel and is deformed when a local excessive load is applied or the liquid crystal contracts in a low temperature environment. A color filter for a liquid crystal display device provided with a columnar spacer, characterized in that the gap between the substrates is kept constant. 2. In a color filter for a liquid crystal display device having a columnar spacer, the columnar spacer has a height and a cross-sectional area corresponding to the deformation due to a load during panel assembly and the deformation following the contraction of liquid crystal in a low temperature environment. The columnar spacers (first columnar spacers) that it has, and the height that is the reference height for properly obtaining the gap between the substrates when assembling the panel, and the height corresponding to the deformation that follows the contraction of the liquid crystal in a low temperature environment, A columnar spacer having a cross-sectional area (second columnar spacer) and a columnar column having a height and a cross-sectional area that keep the gap between the substrates constant when an excessive load is locally applied and the liquid crystal shrinks in a low temperature environment It is composed of three types of column spacers (third column spacers), which maintains a proper gap between the substrates during panel assembly, and also has a local excess. When subjected to a load, or deform when the liquid crystal in a low-temperature environment is contracted, a color filter for a liquid crystal display device provided with a columnar spacer, characterized in that to keep the gap between the substrates constant.