KR20180082772A - Zero retardation plastic substrate film for flexible display - Google Patents

Abstract

Disclosed is a plastic substrate film for a flexible display, capable of compensating and removing a phase difference generated when bending or curving deformation of a flexible display is generated. According to the present invention, the plastic substrate film for a flexible display is applied to a TFT substrate and an optical compensation film substrate of a flexible display implemented by sequentially stacking a circuit board, the TFT substrate, an organic material, an encapsulation thin film, and an optical compensation film, which is configured by coating a substrate having any birefringence with a polymer layer having a birefringence opposite to that of the substrate.

Description

[0001] Zero retardation plastic substrate film for flexible display [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a plastic substrate for a flexible display, and more particularly, to a plastic substrate film for a flexible display capable of compensating for and eliminating a phase difference generated when a flexible display is bent or bent.

Most displays are flat panel displays (FPDs), including liquid crystal displays (LCDs), organic light emitting diodes (OLEDs), and plasma display panels (PDPs) . In recent years, there is a growing interest in a flexible display having a bending characteristic, and a variety of technologies are being developed for this purpose.

On the other hand, the glass substrate used in conventional flat panel displays has a lot of limitations in making flexible flexible displays. Accordingly, a plastic substrate that can be applied to a flexible display has attracted much attention.

The plastic substrate has the advantage of being able to realize a flexible display. Moreover, even if a glass substrate used in a conventional flat panel display is processed as thin as possible, its thickness is limited to 0.4 to 0.5 mm, whereas the plastic substrate has a thickness of 0.2 mm And it is advantageous in that a lighter and thinner display can be realized because the weight is much lighter than the glass substrate by 1/5 or less.

In particular, in recent years, various technologies have been developed to compensate for thermal characteristics, chemical resistance, and flatness, which are weak points of plastic substrates compared with glass substrates, and it is expected that commercialization of flexible displays using plastic substrates will be made soon .

Such a flexible display generally has a structure in which a circuit substrate, a TFT, an organic substance, a sealing film and an optical compensation film are laminated, and a plastic substrate is applied to a substrate for a TFT and a substrate for an optical compensation film.

However, in the flexible display to which the conventional plastic substrate is applied, a phase difference is generated as the plastic substrate is stretched when the flexible substrate is bent, thereby causing a leakage of light in a dark state, thereby deteriorating the quality of the display.

That is, when the plastic substrate is bent, a phase difference occurs because the main chain of the polymer constituting the plastic substrate is rearranged in the bending direction. As a result of this phase difference, light leakage and gradation inversion occur The display quality is deteriorated.

Korean Patent Publication No. 10-2010-0015906 Korean Patent Publication No. 10-2009-0117641

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a plastic substrate for a flexible display which can compensate for and eliminate a phase difference occurring when a flexible display is bent or bent, The present invention has been made in view of the above problems.

In order to achieve the above object, the present invention provides a plastic substrate film for a flexible display, which is used for a plastic substrate of a flexible display panel and an optical compensation film, which film has birefringence opposite to that of the film on a birefringent film And a polymer layer is coated on the surface of the plastic substrate film for a flexible display.

The film may be a polycarbonate film having a positive birefringence (? N), a cycloolefin polymer film, a polyimide film, a polyethylene terephthalate film and a polyether sulfone film sulfone) film.

Here, the film made of the polycarbonate may have a thickness of 95 to 105 mu m.

The polymer layer may comprise polystyrene (PS) or polymethylmethacrylate (PMMA) having a negative birefringence (? N).

Here, the polymer layer made of polystyrene has a thickness of 0.52 to 15.37 μm, and the polymer layer made of polymethyl methacrylate has a thickness of 0.17 to 2.87 μm.

According to the present invention, by controlling the plastic substrate film for a flexible display, it is possible to make the retardation zero even when bending or bending of the flexible display occurs, thereby ensuring the display quality of the flexible display.

Figures 1A-1C are chemical structures of polycarbonate, polystyrene and polymethylmethacrylate, respectively.
Fig. 2 is a schematic diagram showing realignment of main-chain type polymers such as polycarbonate in flat state (a) and bending state (b).
3 is a schematic view of a plastic substrate film according to the present invention.
4A to 4C are graphs showing the retardation [Re (λ)] of the bain polycarbonate film, the polycarbonate film coated with 10 wt% of polystyrene, and the polycarbonate film coated with 30 wt% of polystyrene [1 / R] .
5A and 5B are graphs showing the retardation [Re (λ)] of the polycarbonate film coated with 10 wt% polymethyl methacrylate and the polycarbonate film coated with 30 wt% polymethyl methacrylate, respectively, R].
Figures 6A and 6B are graphs of the retardation [Re (lambda)] versus concentration of polystyrene-coated polycarbonate film and polymethylmethacrylate-coated polycarbonate film, respectively.
7A and 7B are graphs of the retardation Re ([lambda]) of the polystyrene-coated polycarbonate film and the polymethylmethacrylate-coated polycarbonate film versus thickness, respectively.
Figures 8a and 8b are schematic diagrams of molecular reordering in a flat state (a) and a bending state (b) of a substrate film according to the present invention.

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

When the flexible display is bending, the plastic substrate is stretched along the circular arc direction of the film, and a special bending-induced retardation [Re (λ) ≡Δn (λ) d] is observed, and the display quality is degraded by this bending-induced phase difference. Where? _N? N _x -n _y is the in-plain birefringence of the film,? Is the wavelength of light, d is the thickness of the film, n _x And n _y is the in-plane refractive index of the film. That is, the bending-induced phase difference is due to the anisotropic rearrangement of the polymer main-chains along the arc direction of the bended film, and this bending-induced phase difference causes light leakage in the dark state, Resulting in deterioration of image quality.

For example, a main-chain type polymer such as a polycarbonate (PC) having the chemical structure shown in FIG. 1A commonly used as a plastic substrate of a flexible display is used for bending The bending-induced phase difference increases. Referring to Fig. 2, the increase in the bending-induced phase difference of the PC film is due to the anisotropic realignment of the polymer main-chains 2 along the arc direction. That is, the rearrangement of the polymer main-chains is induced to increase toward n _x and the decrease in the direction toward n _y leads to positive birefringence (Δn) and phase difference.

In FIG. 2, left-hand diagram (a) shows the polymer main-chains in anisotropic realignment and polymeric main-chains in the bending state where anisotropic realignment has occurred in the right diagram (b).

In the case of a display device, light leakage in dark-state or gray-scale inversion can be observed by bending-induced phase difference change, and therefore the bending-induced phase difference must be removed from the flexible display.

Accordingly, the present invention coatings the substrate with a thin polymer layer having a birefringence opposite to the birefringence of the substrate film to eliminate the bending-induced phase difference of the plastic substrate film.

3, the present invention can be applied to a PC film 2 having a polystyrene (PS) polymer having a chemical structure as shown in FIG. 1B or a polymer having a chemical structure as shown in FIG. A plastic substrate film 10 for a flexible display having a laminated structure with the PC film 2 and the coating layer 4 is prepared by coating a polymethylmethacrylate (PMMA) polymer. At this time, the PC film 2 has a thickness of 95 to 105 mu m, preferably 100 mu m, the coating layer 4 made of PS polymer has a thickness of 0.52 to 15.37 mu m, and the coating layer 4 made of PMMA polymer ) Has a thickness of 0.17 to 2.87 mu m.

Here, PS polymer and PMMA polymer are side-chain type polymers and exhibit negative birefringence when the film is stretched, bent, or rubbed. Thus, the bending-induced phase difference of the PC film exhibiting positive birefringence can be compensated by the coating layer 4 of PS and PMMA polymer exhibiting negative birefringence.

The characteristics of the zero-phase difference plastic substrate film for a flexible display according to the present invention are as follows.

First, in order to produce a zero-phase difference plastic substrate film, commercially available PS powder or PMMA powder is diluted with a toluene solvent to a weight ratio of 2, 5, 10, 20 and 30 wt%, respectively, Lt; / RTI > for 24 hours. The average molecular weights of PS and PMMA are about 192,000 and 120,000, respectively.

Then, PS solution or PMMA solution was spin-coated on the PC film while the PC film was fixed to the spin chuck, and the solvent was evaporated at 80 캜 for 3 minutes. At this time, the spin coating of the PS solution or the PMMA solution was performed while rotating the spin chuck having the PC film fixed thereto at a constant rate of 1,500 rpm for 15 seconds and at 1,000 rpm for 10 seconds so that the thickness of the coating was uniform.

Here, the PC film is prepared to have a thickness of 95 to 105 mu m, preferably 100 mu m, for example, by a solvent-casting method. The PC film has a small intrinsic retardation (550 nm) of about 5 nm before bending. The present invention measured the phase difference change by bending using Axoscan-OPMF2 (Axometrics), which is a commercial phase contrast measurement system, on the PC film. At this time, while changing the radius of curvature (R) of the PC film, the wavelength? Was changed to 450 nm, 550 nm and 650 nm, and the respective retardations were measured. The probe beam of the phase difference measurement system was made to pass through the center of the PC film, and the in-plane phase difference was measured at the normal incidence angle. For reference, the phase difference resolution of the measurement system is about 0.1 nm, and the thicknesses of the PS film and the PMMA film are measured using an atomic force microscope (AFM).

4A to 4C are graphs of the retardation [Re (?)] Of the bare PC film, the PS 10 wt% coated PC film and the PS 30 wt% coated PC film, respectively, versus the radius of curvature [1 / R].

First, the bare PC film has a small intrinsic retardation of about 5 nm at a wavelength of 550 nm before bending, and the PC film shows a positive birefringence (? N) at which birefringence (? N) decreases at a long wavelength (?). Therefore, the phase difference of the PC film is always reduced as the wavelength (?) Increases through the measurement. The PS-coated PC film is coated with the PS polymer due to the different thermal expansion coefficients of the PC polymer and the PS polymer, and then slightly bent.

Referring to FIG. 4A, the phase difference of the bare PC is increased with an increasing inverse radius of curvature (R ^-1 ), that is, a decreasing radius of curvature R. The increase in the phase difference can be understood as the effect of rearrangement of the PC film main-chains along the arc direction as shown in Fig. ^{R -1 = 12 m -1 (R} = 73㎜) and R ^-1 = 42 in m ^-1 (R = 22㎜), the retardation value of the bare PC of 450㎚ wavelength are each 6.0㎚ and 8.1㎚. Therefore, bare PC film exhibits a special bending-induced phase difference of 2.1 nm. The experimental error of the measured retardation is about 0.3 to 0.7 nm. After bending, the phase difference value of the sample in the flat state is 8.2 nm. The phase difference did not recover exactly when the sample returned to the initial state. The retardation at a wavelength of 550 nm and the retardation at a wavelength of 650 nm were increased by bending.

Therefore, the bending-induced phase difference of the bare PC film is 2.1 nm, which is small enough to lower the image quality of the display device. However, since the result of FIG. 4A is for a single film, and the PC film is applied to the upper and lower substrate films and the lower and upper optical compensation films of the display panel, assuming that four PC films are used for one flexible display, Increasing the phase difference of 2.1 nm of the film leads to an increase of light transmission in a sufficiently dark state.

On the other hand, the results in FIG. 4A are obtained using a solvent-cast PC film which generally exhibits a very small intrinsic retardation, and other films produced by the melt-casting method can exhibit a larger retardation value.

Referring to FIG. 4B, it can be seen that the retardation values are hardly changed for various values of the radius of curvature (R). The PC films coated with 10 wt% PS at R ^-1 = 12 m ^-1 (R = 73 mm) and R ^-1 = 42 m ^-1 (R = 22 mm) had retardations at the wavelength of 450 nm of 5.8 and 5.9 Nm. Thus, a 10 wt% PS-coated PC film shows a bending-induced phase difference of 0.1 nm.

Also, when the sample returns to the initial flat state, the phase difference at a wavelength of 450 nm is 6.5 nm. The retardation at a wavelength of 550 nm and the retardation at a wavelength of 650 nm show smaller changes than the bending compared to a bare PC film. The net phase difference of the PS-coated PC film is obtained as Re (λ) _PC + Re (λ) _PS = Δn _PC d _PC + Δn _PS d _PS . Therefore, a small change in the retardation can be explained by the compensation of the retardation due to the PS film having the birefringence opposite to the birefringence of the PC film.

Referring to FIG. 4C, the phase difference is decreased as the inverse radius of curvature R ^-1 increases, that is, as the radius of curvature R decreases. The retardation values at a wavelength of 450 nm of the 30 wt% PS-coated PC film at R ^-1 = 12 m ^-1 (R = 73 mm) and R ^-1 = 42 m ^-1 (R = 22 mm) And 1.7 nm, and the 30 wt% PS-coated PC film shows a bending-induced phase difference of -4.0 nm. The phase difference at a wavelength of 450 nm observed when the sample returns to its initial state is 6.5 nm.

Therefore, the reduction of the retardation in the bending state can be interpreted to be due to the larger size of the bending-induced phase difference of the PS film than in the PC film.

FIGS. 5A and 5B are graphs showing the retardation [Re (λ)] counter-bending radius [1 / R] of PMMA 10 wt% coated PC film and PMMA 30 wt% coated PC film, respectively.

Referring to FIG. 5A, it can be seen that the increase in phase difference due to bending is reduced by the PMMA coating, as is the case with the PS-coated PC film. The reduction of the bending-induced phase difference of the PMMA-coated PC film can be understood as the effect of rearrangement of the side-chains of the PMMA polymer perpendicular to the arc direction, resulting in negative birefringence.

Referring to FIG. 5B, as in the case of the 30 wt% PS-coated PC film, the retardation decreases with increasing inverse radius of curvature (R ^-1 ). This is because the phase difference _PMMA = the birefringence (DELTA n) _PMMA thickness (d) Because the _PMMA is a retarded _PC due to the increased thickness d of the PMMA layer = Birefringence (? N) _PC thickness (d) means greater than _PC . The decrease in retardation of the PMMA-coated PC film is smaller than the phase difference of the PS-coated PC film at the same concentration.

Figs. 6A and 6B are graphs of the phase difference [Re (lambda)] of the PS-coated PC film and the PMMA-coated PC film versus the PS film and the PMMA film concentration, respectively.

Referring to Figure 6a, the phase difference change [ΔRe (λ)] is defined as a phase difference between the bending states (R ^-1 = 42m ^-1) minus the phase of the bending former (R ^-1 = 12m ^-1). Similar to the results of Figs. 4A to 4C, the phase difference change [Delta] Re ([lambda]) gradually decreases with increasing PS concentration. Based on the linear approximation of the experimental data, the optimized weight fraction of PS is approximately 11 wt%. The thickness of the coating layer increases with increasing PS concentration, resulting in a larger bending-induced phase difference in PS and a smaller phase difference change [Delta] Re ([lambda]) in the whole film.

Referring to Figure 6b, the retardation change [Delta] Re ([lambda]) decreases with increasing PMMA concentration, similar to PS-coated PC film. Based on the linear approximation of the experimental data, the phase difference change can be lowest when the PMMA concentration is about 19 wt%. The phase difference change [Delta] Re ([lambda]) of the PMMA-coated PC film decreases slowly as the solid concentration increases compared to the PS-coated PC film.

The physical reason for the weaker phase compensation effect of the PMMA film compared to the PS film can be explained by the thickness of the PS and PMMA layers. The thickness of the PS and PMMA layers is proportional to the concentration of solids in solution. The thicknesses of the PS layer are 0.52, 1.24, 7.35 and 15.37 탆, respectively, when the solids content is 5, 10, 20 and 30 wt%. On the other hand, the thickness of the PMMA layer is 0.17, 0.64, 2.50 and 2.87 μm when the PMMA concentration is 5, 10, 20 and 30 wt%, respectively. Here, it can be understood that the larger thickness of the PS layer compared to the PMMA layer is due to the larger molar weight of the 192,000 PS layer than the molar weight of 120,000 PMMA.

Figures 7a and 7b are graphs of the retardation [Re ([lambda])] versus thickness of PS-coated PC films and PMMA-coated PC films, respectively.

As shown, the phase difference change decreases with increasing thickness of the PS and PMMA layers, and thus the bending-induced phase difference of the PS and PMMA layers decreases with increasing thickness of the polymer layers. The slopes of the retardation change [DELTA Re ([lambda]] with respect to the thickness of the coating layer are -0.20 and -0.14 in the PS and PMMA coated PC films respectively and the retardation change of the PS- Decrease faster. This can be considered to be due mainly to the chemical structure of the polymers, with different slopes of the phase difference variations in PS and PMMA coated PC films.

That is, as shown in FIGS. 1B and 1C, the side-chains of the PS polymer and the PMMA polymer are aromatic and aliphatic, respectively. The bending forces are more easily transferred to the aromatic side chains than to the aliphatic side chains due to the shapes of the side chains. The side-chains of the PS polymer can therefore be rearranged more easily by bending.

Subsequently, the physical mechanism of the bending-induced phase difference compensation in the PS-coated PC film is as follows.

8A and 8B show the rearrangement of molecules in a flat state and a bending state of a plastic substrate film according to the present invention.

First, the bare PC film has intrinsic phase difference, and as shown in FIG. 8A, the polymers exhibit a random orientation and the side-chains 14 of the PS film as well as the main-chains 12 of the PC film It is randomly oriented before bending.

In this state, when bending occurs in the PC film and the PS film, the main-chains 12 of the PC film are rearranged along the arc direction of the film, resulting in positive birefringence and phase difference. On the other hand, the side-chains 14 of the PS film are rearranged perpendicular to the arc direction, which is the result of the side-chains 14 having negative birefringence and phase difference. Thus, the bending-induced phase difference of the PC substrate can be compensated by the PS layer.

As described above, the present invention coats a substrate film having any birefringence with a polymer having an opposite birefringence. That is, the PC film is a main-chain-type polymer and has positive birefringence when the film is bent. On the other hand, PS and PMMA are side-chain polymers and exhibit negative birefringence when their films are bent. Therefore, by coating PS or PMMA polymer on a PC film as a plastic substrate film of a flexible display, it is possible to realize zero phase difference even when the plastic substrate is bent, thereby preventing light leakage in a dark state The quality of the display can be ensured.

Meanwhile, in the above-described embodiments of the present invention, the case where the PC polymer is applied as the substrate film has been described. However, as another example, a cycloolefin polymer (COP), a polyimide polyimide (PI) polymer, polyethylene terephthalate (PET) polymer, and polyether sulfone (PS) polymer.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be readily apparent to those skilled in the art that the present invention can be modified and changed without departing from the scope of the present invention.

2: Polycarbonate film 4: Coating layer
10: plastic substrate film 12: main-chain
14: Side-chain

Claims (5)

A plastic substrate film for a flexible display used for a flexible display panel and an optical compensation film,
Characterized in that a polymer layer having birefringence opposite to that of the film is coated on a film having an arbitrary birefringence.
The method according to claim 1,
The film may be a polycarbonate (PC) film having a positive birefringence (? N), a cycloolefin polymer (COP) film, a polyimide (PI) film, a polyethylene terephthalate ET) film and a polyether sulfone (PES) film. The plastic substrate film for a flexible display according to claim 1,
The method according to claim 1,
Wherein the film made of the polycarbonate has a thickness of 95 to 105 占 퐉.
The method according to claim 1,
Wherein the polymer layer comprises polystyrene (PS) or polymethylmethacrylate (PMMA) having a negative birefringence (? N).
5. The method of claim 4,
Wherein the polymer layer made of polystyrene has a thickness of 0.52 to 15.37 占 퐉 and the polymer layer made of polymethyl methacrylate has a thickness of 0.17 to 2.87 占 퐉.

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