KR100931719B1 - Organic light emitting display - Google Patents

Abstract

The present invention relates to an organic light emitting display device, comprising: an EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; And a phase delay layer provided between the polarizing film and the EL light emitting display element with liquid crystal polymer having birefringence.

As a result, an organic light emitting display device having improved product yield, ultra-thin film formation, and light loss is prevented.

Organic electroluminescence, EL, polarization, phase delay, thin film, light loss

Description

Organic Luminescence display device

The present invention relates to an organic light emitting display device, and more particularly, to an organic light emitting display device having an improved structure of a polarizing film and a phase delay layer that suppress reflection effects on an external light source.

In general, since the organic light emitting display device emits light by itself, the device can be thinner, lighter in weight, and low power, and the response speed is faster than the liquid crystal display device having a separate backlight unit. There is an advantage such that no afterimage remains, which has attracted much attention as the next generation display device.

However, such an organic light emitting display device has a problem in that the visibility of the screen is remarkably degraded due to the reflection of light incident from the outside in an environment with abundant external light.

Accordingly, as shown in FIG. 1, the polarizing film 130 and the phase delay film 120 are disposed between the EL light emitting display device 110 and the external light transmitting plate 140 of the organic light emitting display device 101. A technique for improving the visibility of a screen is developed by suppressing a reflection action of light incident from the outside via the device.

On the other hand, the phase delay film 120 in the conventional organic light emitting display device 101 is to stretch the polymer film to have a phase delay value for the polarized light incident through the polarizing film 130 from the outside.

The light incident from the outside by the optical structure is absorbed part of the polarization in the polarizing film 130, the remaining polarized light passing through the polarizing film 130 passes through the phase delay film 120, the EL light emitting display device 110 After the reflection, the reflected light is phase-delayed through the phase delay film 120 and absorbed by the polarizing film 130, thereby suppressing the reflection of external incident light to improve the visibility of the screen.

However, in such a conventional organic light emitting display device, since the phase delay film is provided as an optical component separate from the polarizing film and the EL light emitting display element, the phase delay film is interposed between the polarizing film and the EL light emitting display element. In order to be laminated, an adhesive material (“A” in FIG. 1) must be used on both sides of the phase delay film.

As a result, a problem of a decrease in product yield occurred, and adhesive layers were formed on both sides of the phase delay film, thereby causing a problem in that the thinning of the product was limited.

In particular, since the phase delay film prepared by stretching the polymer film generally has a relatively thick thickness of 70 ~ 80μm, there is a problem that further limit the thinning of the product.

In addition, since the thickness of the phase delay film is relatively thick, the transmittance of light emitted from the EL light emitting display device is lowered, resulting in a problem of light loss.

In addition, there is a problem that the production of the product is not easy due to the increase in the difficult adhesion process.

Accordingly, it is an object of the present invention to provide an organic light emitting display device in which the yield of the product is improved, the ultra-thin film is made, the light loss is prevented, and the production of the product is easy.

According to the present invention, there is provided an organic electroluminescent display device, comprising: an EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; It is achieved by an organic electroluminescent display device comprising a phase delay layer formed of a liquid crystal polymer having birefringence between the polarizing film and the EL light emitting display element.

Here, the polarizing film is preferably laminated with an adhesive material on the lower surface of the external light transmitting plate.

In addition, the phase delay layer is effectively provided by laminating and curing the liquid crystal polymer in the liquid state on the lower surface of the polarizing film.

Alternatively, the phase delay layer is more preferably formed by laminating and curing a liquid crystal polymer in a liquid state on the upper surface of the EL light emitting display element.

At this time, it is more effective that the lower surface of the polarizing film and the upper surface of the phase delay layer are bonded to each other with an adhesive material.

In addition, the phase delay layer is preferably laminated and cured integrally on the lower surface of the polarizing film in a state in which the liquid crystal polymer in the liquid state is laminated on the upper surface of the EL light emitting display device.

At this time, it is effective that the thermal expansion coefficient (A) of the polarizing film and the thermal expansion coefficient (B) of the phase delay layer have a relationship of A> B.

B의 관계를 갖는 것이 바람직하다.In addition, the thermal expansion coefficient (A) of the polarizing film, the thermal expansion coefficient (B) of the phase delay layer, and the thermal expansion coefficient (C) of the adhesive material are A> C.

It is preferable to have a relationship of B.

Alternatively, it is effective that the thermal expansion coefficient (A) of the polarizing film, the thermal expansion coefficient (B) of the phase delay layer, and the thermal expansion coefficient (C) of the adhesive material have a relationship of C> A> B.

B

D의 관계를 갖는 것이 바람직하다. In addition, the thermal expansion coefficient (A) of the polarizing film, the thermal expansion coefficient (B) of the phase delay layer, the thermal expansion coefficient (C) of the adhesive material and the thermal expansion coefficient (D) of the external light transmitting plate are A> C.

B

It is preferable to have a relationship of D.

D의 관계를 갖는 것이 효과적이다. Alternatively, the thermal expansion coefficient (A) of the polarizing film, the thermal expansion coefficient (B) of the phase delay layer, the thermal expansion coefficient (C) of the adhesive material, and the thermal expansion coefficient (D) of the external light transmitting plate may be C>A> B.

It is effective to have a relationship of D.

On the other hand, it is more preferable that an alignment film is provided on at least one surface of the phase delay layer.

As a result, an organic light emitting display device having improved product yield, ultra-thin film formation, and light loss is prevented.

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

2 is a cross-sectional view of an organic light emitting display device according to an embodiment of the present invention. As shown in the figure, the organic light emitting display device 1 according to the present embodiment is disposed on the lower surface of the external light transmitting plate 40 in the region between the EL light emitting display element 10 and the external light transmitting plate 40. The polarizing film 30 is laminated, and the phase delay layer 20 is interposed between the lower part of the polarizing film 30 and the upper part of the EL light emitting display device 10.

Among these, the polarizing film 30 is prepared in the form of a film in advance, and is laminated on the lower surface of the outer transparent plate 40 using the adhesive material 50. The polarizing film 30 transmits the linearly polarized light in a specific direction of the external incident light, and absorbs the linearly polarized light in the other direction. The linearly polarized light transmitted through the polarizing film 30 is a phase delay layer 20 which will be described later. Phase delayed by one-way circularly polarized light.

On the other hand, the phase delay layer 20 is preferably formed by a method of curing the liquid crystal polymer having a birefringence in the liquid state directly on the lower surface of the polarizing film 30, and then hardened, the phase delay layer 20 ) Can be adjusted according to the birefringence (Δn) of the liquid crystal polymer and the stacking thickness (d) of the liquid crystal polymer, as shown in Equation-1 below.

Δλ = Δn × d equation-1

(Where Δλ is the phase delay value, Δn is the birefringence of the liquid crystal polymer, and d is the lamination thickness of the liquid crystal polymer)

At this time, the birefringence Δn of the liquid crystal polymer is 0.1 to 0.2, and particularly preferably has a range of 0.1 to 0.14. A graph of the distribution of the lamination thickness d of the liquid crystal polymer according to the birefringence Δn of the liquid crystal polymer is shown in FIG. 6. According to the graphs of Equation-1 and FIG. 1, the thickness of the phase delay layer 20 at about λ = 660 nm may have a thickness of 4 μm or less, in particular, 2 μm or less.

The phase delay layer 20 may adjust the phase delay value Δλ according to the change in the stack thickness d of the liquid crystal polymer capable of implementing an ultra-thin film, and may significantly thin the organic light emitting display device 1. .

In addition, by laminating the phase delay layer 20 integrally on the polarizing film 30, the adhesive material is reduced because the adhesive material is not used. Accordingly, it is possible to implement a thin film, the process using the adhesive is reduced, the yield is increased, and the process is simplified.

The phase delay layer 20 can be firmly fixed by attaching a lower surface thereof to the upper surface of the EL light emitting display device 10 with the adhesive material 50.

D의 관계를 갖도록 하며, 더불어 편광필름(30)의 열팽창계수(A)와 위상지연층(20)의 열팽창계수(B) 및 접착물질(50)의 열팽창계수(C)와 외부광투과판(40)의 열팽창계수(D)는 A > C

B

D 또는 C > A > B

D의 관계를 갖도록 함으로써, 장치의 동작 및 주변 환경에 의해 발생하는 상호 적층구조 간의 열적변형을 최소화하는 것이 바람직하다. Here, the thermal expansion coefficient (A) of the polarizing film 30 and the thermal expansion coefficient (B) of the phase delay layer (20) have a relationship of A> B, and the thermal expansion coefficient (A) and phase delay of the polarizing film (30). The coefficient of thermal expansion (B) of the layer 20 and the coefficient of thermal expansion (D) of the external light transmitting plate 40 are A> B

The thermal expansion coefficient (A) of the polarizing film 30, the thermal expansion coefficient (B) of the phase delay layer 20, the thermal expansion coefficient (C) of the adhesive material 50 and the external light transmitting plate ( The coefficient of thermal expansion (D) of 40) is A> C

B

D or C>A> B

By having a relationship of D, it is desirable to minimize thermal deformation between the interlaminar structures generated by the operation of the device and the surrounding environment.

The reflection suppression effect on the external incident light of the organic light emitting display device 1 according to the present invention having the optical structure will be described.

Of the light incident from the outside, linearly polarized light in a specific direction (hereinafter referred to as "Y-axis polarization") is absorbed by the polarizing film 30, and linearly polarized light in the other direction (hereinafter referred to as "X-axis polarization") is polarized film. Passed through 30 is incident to the phase delay layer 20.

The X-axis polarized light incident on the phase delay layer 20 is changed to one direction circularly polarized light (hereinafter referred to as "right circular polarization") while passing through the phase delay layer 20, and then the phase delay layer in the EL light emitting display device 10. Reflected upward toward (20), the direction is converted into circularly polarized light in the opposite direction (hereinafter referred to as "left circularly polarized light").

Then, the reflected left circularly polarized light is phase-delayed by Y-axis polarization while passing through the phase delay layer 20, and the Y-axis polarization is absorbed without passing through the polarizing film 30.

As a result, the reflection effect on the external incident light is suppressed, and the screen visibility of the organic light emitting display device 1 is improved.

Here, the rightward circularly polarized light and the leftward circularly polarized light are polarization directions selected for convenience of description and may be different from the actual polarization directions.

In addition, since the organic light emitting display device 1 according to the present invention is formed of a liquid crystal polymer capable of forming the phase delay layer 20 into an ultra-thin film, it is possible to make the device significantly thinner.

In addition, since the external light transmitting plate 40, the polarizing film 30, the phase delay layer 20, and the EL light emitting display device 10 are stacked in close contact with each other without being spaced apart from each other, surface reflection occurs at an interface between adjacent optical parts. I never do that.

As a result, a decrease in transmittance of the light emitted from the EL light emitting display element 10 to the phase delay layer 20 is minimized, and light loss is significantly prevented.

In addition, by the thinning of the phase delay layer 20, the transmittance and the light loss of the light emitted from the EL light emitting display device 10 are further prevented.

In addition, by laminating the phase delay layers 20 integrally on the lower surface of the polarizing film 30 without using an adhesive material, the product yield is improved, the device can be further thinned, and the product is removed by eliminating the difficult adhesion process. It is made easy to manufacture.

3 to 5 are cross-sectional views of an organic light emitting display device according to other embodiments of the present invention. These embodiments have the same polarizing film 30 and the phase delay layer 20 as in the embodiment of FIG. 2, but the EL light emitting display device 10, the polarizing film 30, and the phase delay layer 20 are external to each other. The mutually laminated structure of the light transmissive plates 40 is different.

Therefore, hereinafter, the detailed description of the polarizing film 30 and the phase delay layer 20 is replaced with the embodiment of FIG. 2 described above, and the EL light emitting display device 10 and the polarizing film 30 and The mutually laminated structure of the phase delay layer 20 and the external light transmitting plate 40 will be described.

First, according to the exemplary embodiment shown in FIG. 3, the polarizing film 30 is laminated on the lower surface of the outer transparent plate 40 using the adhesive material 50, and the liquid is formed on the upper surface of the EL light emitting display device 10. In the state where the phase delay layer 20 is formed by directly laminating and curing the liquid crystal polymer having birefringence in a state, the lower surface of the polarizing film 30 and the upper surface of the phase delay layer 20 are bonded to the adhesive material 50. The organic light emitting display device 1 may be provided by attaching to each other.

D의 관계를 갖도록 하며, 더불어 편광필름(30)의 열팽창계수(A)와 위상지연층(20)의 열팽창계수(B) 및 접착물질(50)의 열팽창계수(C)와 외부광투과판(40)의 열팽창계수(D)는 A > C

B

D 또는 C > A > B

D의 관계를 갖도록 함으로써, 장치의 동작 및 주변 환경에 의해 발생하는 상호 적층구조 간의 열적변형을 최소화하는 것이 바람직하다. In this embodiment, the coefficient of thermal expansion A of the polarizing film 30 and the coefficient of thermal expansion B of the phase delay layer 20 have a relationship A> B, and the coefficient of thermal expansion A of the polarizing film 30. The thermal expansion coefficient B of the phase delay layer 20 and the thermal expansion coefficient D of the external light transmitting plate 40 are A> B.

The thermal expansion coefficient (A) of the polarizing film 30, the thermal expansion coefficient (B) of the phase delay layer 20, the thermal expansion coefficient (C) of the adhesive material 50 and the external light transmitting plate ( The coefficient of thermal expansion (D) of 40) is A> C

B

D or C>A> B

By having a relationship of D, it is desirable to minimize thermal deformation between the interlaminar structures generated by the operation of the device and the surrounding environment.

Since the organic light emitting display device 1 according to the present embodiment also forms the liquid crystal polymer capable of forming the phase delay layer 20 in an ultra-thin film, it is possible to make the device significantly thinner.

In addition, since the external light transmitting plate 40, the polarizing film 30, the phase delay layer 20, and the EL light emitting display device 10 are stacked in close contact with each other without being spaced apart from each other, surface reflection occurs at an interface between adjacent optical parts. I never do that.

As a result, a decrease in transmittance of the light emitted from the EL light emitting display element 10 to the phase delay layer 20 is minimized, and light loss is significantly prevented.

In addition, the thin film of the phase delay layer 20 prevents light transmittance and light loss emitted from the EL light emitting display device 10.

In addition, by integrally stacking the phase delay layer 20 on the upper surface of the EL light emitting display device 10 without using an adhesive material, the product yield can be improved, the device can be further thinned, and the difficult adhesion process is eliminated. The manufacture of the product is made easy.

On the other hand, according to the embodiment shown in Figure 4, the polarizing film 30 is laminated on the lower surface of the outer transparent plate 40 using the adhesive material 50, and the liquid on the upper surface of the EL light emitting display device 10 The organic light emitting display device 1 may be provided by directly stacking the liquid crystal polymer having birefringence in a state and then laminating and curing the upper surface of the phase delay layer 20 on the lower surface of the polarizing film 30.

D의 관계를 갖도록 하며, 더불어 편광필름(30)의 열팽창계수(A)와 위상지연층(20)의 열팽창계수(B) 및 접착물질(50)의 열팽창계수(C)와 외부광투과판(40)의 열팽창계수(D)는 A > C

B

D 또는 C > A > B

D의 관계를 갖도록 함으로써, 장치의 동작 및 주변 환경에 의해 발생하는 상호 적층구조 간의 열적변형을 최소화하는 것이 바람직하다. In this embodiment, the coefficient of thermal expansion A of the polarizing film 30 and the coefficient of thermal expansion B of the phase delay layer 20 have a relationship A> B, and the coefficient of thermal expansion A of the polarizing film 30. The thermal expansion coefficient B of the phase delay layer 20 and the thermal expansion coefficient D of the external light transmitting plate 40 are A> B.

The thermal expansion coefficient (A) of the polarizing film 30, the thermal expansion coefficient (B) of the phase delay layer 20, the thermal expansion coefficient (C) of the adhesive material 50, and the external light transmitting plate ( The coefficient of thermal expansion (D) of 40) is A> C

B

D or C>A> B

By having a relationship of D, it is desirable to minimize thermal deformation between the interlaminar structures generated by the operation of the device and the surrounding environment.

In the organic light emitting display device 1 according to the present exemplary embodiment, the polarization film 30, the phase delay layer 20, and the EL light emitting display device 10 are laminated integrally with each other without using an adhesive material. Product yield and device thinning and ease of product manufacture can be further improved.

Meanwhile, according to the exemplary embodiment illustrated in FIG. 5, the alignment layer 60 may be provided on at least one surface of the phase delay layer 20.

The alignment layer 60 is to improve the orientation of the liquid crystal polymer forming the phase retardation layer 20. In general, the polyimide material is coated on the surface on which the phase retardation layer 20 is laminated, followed by a rubbing process. It is preferable to form the phase retardation layer 20 by the method of orienting and increasing an orientation force using this, and apply | coating and orienting liquid crystal polymer on this alignment film.

Of course, the alignment layer 60 may use other alignment materials in addition to polyimide, and may be applied to all the above-described embodiments.

As described above, the organic light emitting display device according to the present invention is formed of liquid crystal polymer capable of forming the phase delay layer into an ultra-thin film, and thus the device can be made thin.

In addition, the polarizing film, the phase delay layer, and the EL light emitting display devices are stacked in close contact with each other without being spaced apart from each other, and the thin film is formed, thereby minimizing the decrease in the transmittance of light emitted from the EL light emitting display device, thereby significantly preventing light loss.

In addition, by eliminating or minimizing the use of adhesive materials, product yields are improved, the device can be made even thinner, and the manufacture of products is facilitated by eliminating difficult adhesive processes.

1 is a schematic cross-sectional view of a conventional organic light emitting display device;

2 is a schematic cross-sectional view of an organic light emitting display device according to an embodiment of the present invention;

3 to 7 are schematic cross-sectional views of an organic light emitting display device according to another embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

10 EL display device 20 phase delay layer

30 polarizing film 40 external light transmitting plate

50: adhesive material 60: alignment layer

Claims (12)

delete delete In an organic light emitting display device, An EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; A phase delay layer provided between the polarizing film and the EL light emitting display element with liquid crystal polymer having birefringence; And the phase delay layer is formed by integrally stacking and curing a liquid crystal polymer in a liquid state on a lower surface of the polarizing film. In an organic light emitting display device, An EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; A phase delay layer provided between the polarizing film and the EL light emitting display element with liquid crystal polymer having birefringence; And the phase delay layer is formed by stacking and curing a liquid crystal polymer in a liquid state on an upper surface of the EL light emitting display device. The method of claim 4, wherein And a lower surface of the polarizing film and an upper surface of the phase delay layer are bonded to each other with an adhesive material. In an organic light emitting display device, An EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; A phase delay layer provided between the polarizing film and the EL light emitting display element with liquid crystal polymer having birefringence; And the phase delay layer is integrally laminated and cured on the lower surface of the polarizing film in a state in which a liquid crystal polymer in a liquid state is laminated on the upper surface of the EL light emitting display device. In an organic light emitting display device, An EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; A phase delay layer provided between the polarizing film and the EL light emitting display element with liquid crystal polymer having birefringence; And a thermal expansion coefficient (B) of the polarizing film and a thermal expansion coefficient (B) of the phase delay layer having an A> B relationship. In an organic light emitting display device, An EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; A phase delay layer provided between the polarizing film and the EL light emitting display element with liquid crystal polymer having birefringence; The polarizing film is laminated with an adhesive material on the lower surface of the external light transmitting plate, The thermal expansion coefficient (A) of the polarizing film, the thermal expansion coefficient (B) of the phase delay layer, and the thermal expansion coefficient (C) of the adhesive material are A> C

An organic light emitting display device having a B relationship. In an organic light emitting display device, An EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; A phase delay layer provided between the polarizing film and the EL light emitting display element with liquid crystal polymer having birefringence; The polarizing film is laminated with an adhesive material on the lower surface of the external light transmitting plate, And a thermal expansion coefficient (C) of the polarizing film, a thermal expansion coefficient (B) of the phase delay layer, and a thermal expansion coefficient (C) of the adhesive material, having a relationship of C> A> B. In an organic light emitting display device, An EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; A phase delay layer provided between the polarizing film and the EL light emitting display element with liquid crystal polymer having birefringence; The polarizing film is laminated with an adhesive material on the lower surface of the external light transmitting plate, The thermal expansion coefficient (A) of the polarizing film, the thermal expansion coefficient (B) of the phase delay layer, the thermal expansion coefficient (C) of the adhesive material, and the thermal expansion coefficient (D) of the external light transmitting plate are A> C.

B

An organic light emitting display device having a D relationship. In an organic light emitting display device, An EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; A phase delay layer provided between the polarizing film and the EL light emitting display element with liquid crystal polymer having birefringence; The polarizing film is laminated with an adhesive material on the lower surface of the external light transmitting plate, The thermal expansion coefficient (A) of the polarizing film, the thermal expansion coefficient (B) of the phase delay layer, the thermal expansion coefficient (C) of the adhesive material, and the thermal expansion coefficient (D) of the external light transmitting plate are C>A> B

An organic light emitting display device having a D relationship. In an organic light emitting display device, An EL light emitting display element; An external light transmitting plate provided above the EL light emitting display element; A polarizing film provided on a lower surface of the external light transmitting plate in a region between the EL light emitting display element and the external light transmitting plate; A phase delay layer provided between the polarizing film and the EL light emitting display element with liquid crystal polymer having birefringence; An organic light emitting display device, characterized in that an alignment layer is provided on at least one surface of the phase delay layer.

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