JP2005332587A - Organic el device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make an organic EL (Electro Luminescence) device effectively function as a mirror. <P>SOLUTION: This organic EL display device is provided with an image display mode and a mirror finished surface mode which functions as the mirror. The organic EL display device functions as the mirror with illumination. Partial display areas 313, 314 are brought into non-luminescent conditions, and the display area thereby generates a mirror finished surface effect. In addition, a DC voltage is given to a display area 312 adjacent to the mirror finished surface area which functions as the mirror to make the display region function as illumination. The illuminating area 312 makes the function as the mirror finished surface of the organic EL display device more effective. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an organic EL (Electro Luminescence) device, and more particularly to an organic EL device that functions as a mirror.

With the recent rapid technological development in the information and communication field, there is a great expectation for a flat display replacing CRT. In particular, organic EL (Electro Luminescence) displays are actively studied because they are excellent in terms of high-speed response, visibility, brightness, and the like. The original organic EL device structure has a two-layer structure of organic thin films, uses tris aluminum for the light emitting layer, emits green light when driven at a low voltage of 10 V or less, and has a luminance of 1000 cd / m ^2. It was.

  In recent studies, various stacked organic EL devices having about 1 to 10 organic layers sandwiched between a hole injection electrode (anode) and an electron injection electrode (cathode) have been developed. With respect to organic EL materials, those using low molecules or those using polymers have been studied. As a method for producing an organic EL element, not only a method of forming a thin film of a low molecular compound by a vacuum deposition method, but also a method of forming a thin film of a polymer compound by a method such as spin coating, ink jet, die coating, flexographic printing, etc. A method for forming an element has been proposed.

  The organic EL element causes the organic EL element to emit light by current drive by applying a voltage between an anode and a cathode sandwiching the organic thin film layer. As a driving method, active driving using a switching element for selecting an organic EL element constituting a pixel, or passive driving not using a switching element is known. As the organic EL display, there are known an organic EL display that performs display by monochromatic light emission, an area color display that displays partially different colors, or a display that performs full color display. The monochromatic organic EL display includes a monochromatic organic EL element. For example, an organic EL element that emits red, blue, green, or white light is known.

  Typically, the cathode is formed of a light reflective metal such as Al or Li, and the anode is formed of a transparent conductive film such as ITO (indium / tin / oxide). For this reason, the cathode reflects light from the outside, reducing the contrast of the image. In order to suppress a reduction in contrast due to external light reflection, a circular polarizing plate is attached to the viewing side of the substrate in a normal organic EL display device. The circularly polarizing plate has functions of a ¼λ plate and a polarizing plate (linear polarizing plate), and can block the reflected light of light incident from the outside.

  On the other hand, an image display device that functions as a mirror in addition to image display using a liquid crystal display device has been proposed. For example, Patent Document 1 proposes a backlight image display device that can be used as a mirror as well as an original lighting device. In addition to a liquid crystal display device (or a transmissive printing film) on which an image to be displayed is formed, the backlight type image display device includes a half mirror member on the front surface thereof. By irradiating light from the back surface of the liquid crystal display device with a backlight, an image can be observed from the front surface of the half mirror member through the half mirror member. Further, when the backlight is turned off, the half mirror member can be used as a mirror.

Japanese Patent Laid-Open No. 11-15392

  As described above, proposals have been made to display an image with an image display device and to use it as a mirror. However, when a half mirror is used as in the above example, there is a problem that the brightness of the display image is lowered when an image is displayed by a liquid crystal display device. In addition, when the image display device functions as a mirror using a half mirror, there is a problem that a necessary reflected image cannot be projected when the periphery is dark.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an organic EL device that effectively functions as a mirror. The above and other objects and novel features of the present invention will be apparent from the description of this specification and the accompanying drawings.

  Means for solving the problems are disclosed below. In this item, some components are associated with the components described in the embodiments. However, this association is made for easy understanding of the invention, and each element is not limited to the corresponding element in the embodiment.

  The first aspect of the present invention is a light emitting region (for example, display region) that emits light by supplying a driving current to an organic light emitting layer (for example, organic EL layer 103) via an internal metal layer (for example, cathode 104 and cathode wiring). 311), the light-emitting region is switched between a light-emitting state and a non-light-emitting state, and functions as a mirror by specularly reflecting external light by the internal metal layer in the non-light-emitting state. It has a mirror surface area (for example, divided display area 312) and an illumination area (for example, divided display areas 313 and 314) that emits illumination light by DC driving the organic light emitting layer.

  The organic EL device includes a first mode for displaying an image and a second mode that functions as a mirror. The mirror surface area displays an image in the first mode, and in the second mode. It preferably functions as a mirror by specular reflection, and the illumination area displays an image in the first mode and emits illumination light in the second mode. By providing a plurality of modes, different usages of the organic EL device can be selected depending on the situation.

  The light emitting region is composed of a plurality of divided regions, a part of the plurality of divided regions emits illumination light by DC driving, and the other regions of the plurality of divided regions are in the inner metal layer. It is preferable to function as a mirror by specularly reflecting external light. Thereby, a mirror surface area and an illumination area can be formed with a simple configuration. Furthermore, it is preferable to further include a controller (for example, a controller 331) that selects the illumination area and the specular area from the plurality of divided areas. Since the illumination region and the mirror surface region can be selected, the illumination and mirror surface can be controlled according to the situation.

  The light emitting region includes a plurality of first electrode wiring layers (for example, cathode wiring) arranged in a first direction and a plurality of second electrode wirings disposed so as to overlap the plurality of first electrode wiring layers. And the illumination region is defined by all of the plurality of second electrode wiring layers and a part of the first electrode wiring layers arranged in succession. Is preferred. Thereby, a mirror surface area and an illumination area can be formed with a simple configuration.

  The organic EL device includes a first mode that functions as illumination and a second mode that functions as a mirror, and the mirror surface region emits illumination light by DC driving in the first mode, and the first mode In the second mode, it functions as a mirror by specular reflection, and the illumination area preferably emits illumination light by DC driving in the first and second modes. By providing a plurality of modes, different usages of the organic EL device can be selected depending on the situation.

  According to the present invention, the organic EL device can effectively function as a mirror.

  Hereinafter, embodiments to which the present invention can be applied will be described. The following description is to describe the embodiment of the present invention, and the present invention is not limited to the following embodiment. For clarity of explanation, the following description and drawings are omitted and simplified as appropriate. Moreover, those skilled in the art can easily change, add, and convert each element of the following embodiments within the scope of the present invention. In addition, in each drawing, the same code | symbol is attached | subjected to the same element and the duplication description is abbreviate | omitted as needed for clarification of description.

  The organic EL (Electro Luminescence) display device of this embodiment functions as a mirror with illumination. By setting a part of the display area to the non-light emitting state, the part of the display area has a mirror effect. Further, by applying a DC voltage to the display area adjacent to the mirror area that functions as a mirror, the display area functions as illumination. This illumination area can make the function as a mirror surface of the organic EL display device more effective. First, in order to facilitate understanding of the present invention, an outline of an organic EL display device, particularly, an organic EL light emitting element constituting a pixel will be described. In the following, a passive matrix organic EL display device will be described as an example.

  In general, an organic EL display device includes an organic EL element substrate on which a plurality of organic EL light emitting elements are formed, and a counter substrate for sealing the plurality of organic EL light emitting elements on the organic EL element substrate. FIG. 1 shows an outline of a configuration example of an organic EL light emitting device. The organic EL light emitting device 100 includes a glass substrate 101, an anode 102 formed on the glass substrate 101, a thin film organic compound (organic EL layer) 103 laminated on the anode 102 and including an organic light emitting layer, A cathode 104 is provided on the organic EL layer 103 so as to face the anode. Further, the sealing substrate 105 facing the glass substrate 101 is fixed to the glass substrate 101 with a sealing agent. The sealing substrate 105 maintains the anode 102, the organic EL layer 103, and the cathode 104 in a sealed state, and prevents moisture from entering from the outside. Further, on the inner surface of the sealing substrate 105, a water capturing agent 106 that captures moisture inside is disposed.

  The organic EL light emitting device 100 is a current-driven display device that emits light when a current is supplied to the organic EL layer 103 disposed between the anode 102 and the cathode 104 that are provided to face each other. The organic EL layer 103 can be configured by, for example, stacking CuPc, NPD, Alq, and LiF layers from the anode 102 side. Alq emits light by supplying current. The film thickness of each layer can be set to, for example, 50 nm, 200 nm, 30 nm, and 0.5 nm.

  The organic EL light emitting device 100 emits light by supplying a high potential to the anode 102, applying a predetermined voltage between both electrodes and supplying a current to the organic EL layer 103. Conversely, when the cathode side 104 is set to a high potential, no current flows through the organic EL layer 103 and the organic EL light emitting device 100 does not emit light. When driving the organic EL light emitting device 100, a constant current driving method is generally used. That is, in order to obtain a predetermined light emission luminance, a drive circuit (not shown) provided with a constant current circuit supplies a constant current to the organic EL light emitting element.

  In general, a plurality of anode wirings connected to the anode 102 or forming the anode itself are arranged in parallel on the glass substrate 101. In addition, a plurality of cathode wirings connected to the cathode 104 or forming the cathode itself are arranged in parallel in a direction orthogonal to the anode wiring. In an organic EL display device in which anode wiring and cathode wiring are arranged in a matrix, intersections between the anode wiring and the cathode wiring serve as pixels (organic light emitting elements), and the pixels are arranged in a matrix. The cathode 104 and the cathode wiring are made of a light reflective metal such as Al or Li alloy, and the cathode 104 and the cathode wiring mirror-reflect light. The anode 102 and the anode wiring are formed of a transparent conductive film such as ITO (indium / tin / oxide).

  When an organic EL display device in which anode wiring and cathode wiring are arranged in a matrix is driven by a simple matrix driving method, one of the anode wiring and the cathode wiring is used as a scanning electrode, and the other is used as a data electrode. . Then, a scan electrode driving circuit including a constant voltage circuit is connected to the scan electrode, and the scan electrode is driven at a constant voltage. Then, one of the scan electrodes is sequentially scanned every predetermined period to be in a selected state, and the other scan electrodes are in a non-selected state.

  A data electrode driving circuit having a constant current circuit at the output stage is connected to the data electrode. Then, a current corresponding to the display data of the row corresponding to the scan electrode in the selected state is supplied to each data electrode in synchronization with the scan. The current supplied from the constant current circuit to the data electrode flows through the organic EL layer 103 located at the intersection of the scan electrode and the data electrode in the selected state to the scan electrode in the selected state. The pixel emits light in a period in which the scan electrode forming the pixel is in a selected state and current is supplied from the data electrode. Further, when the supply of current from the data electrode is stopped, the light emission is also stopped. When driving, the anode wiring of the organic EL display device may be a scanning electrode or a data electrode.

  As described above, the cathode 104 and the cathode wiring are formed of a light-reflective metal layer, and the cathode wiring (and the cathode 104) specularly reflects light from the outside. In particular, in the state where the organic EL layer 103 does not emit light, only the reflected light is emitted without emitting the emitted light to the viewing side, so that an effective mirror effect is achieved. The organic EL display device of this embodiment functions as a mirror using this characteristic.

  A typical organic EL display device includes a circularly polarizing plate on the outside of the glass substrate 101 in order to prevent reflection of external light by a reflective metal. Since the organic EL display device of this embodiment functions as a mirror that reflects external light, the circularly polarizing plate for preventing reflection is not attached to the glass substrate 101. The reflected light of the electrode and the electrode wiring is emitted to the viewing side without passing through the circularly polarizing plate. If necessary, an optical film such as a UV cut filter or a prism film can be provided on the viewing side of the glass substrate 101.

  FIG. 2 shows a preferable display state of the display region 200 when the organic EL display device of this embodiment is used as a mirror. In FIG. 2, 201 is a non-light emitting display area in which each pixel is in a non-light emitting state, and 202 is a light emitting display area in which each pixel is in a self light emitting state. The non-light-emitting display area 201 can function as a mirror because the electrode in the area effectively mirrors external light. On the other hand, the light emitting display area 202 emits light with a predetermined luminance by self light emission.

  For this reason, the light emitting display area 202 functions as illumination, and the mirror surface function by the non-light emitting display area 201 can be further enhanced. In order to function as illumination, the luminance of the light emitting display area 202 is preferably high. Further, in order to enhance the mirror effect of the non-light emitting display area 201, the light emitting display area 202 is DC driven (for example, DC 10V driven), and emits light with a predetermined luminance.

  As shown in FIG. 2, the light emitting display region 202 is preferably defined by a part of row electrode wirings arranged continuously and all column electrode wirings. Thereby, the light emitting display area 202 can be easily controlled. In addition, it is a preferable example that the light-emitting display region 202 is defined by a part of column electrode wirings arranged continuously and all the row electrode wirings. The non-light emitting display area 201 that functions as a mirror surface preferably has a wide continuous area. For this reason, the light emitting display area 202 is preferably formed at the end of the display area as shown in FIGS.

  The area of the light emitting display area 202 is set to an appropriate value from the viewpoint of the function as illumination. It is also possible to form the light emitting display area 202 divided into two or more areas. In addition, in order to function as illumination, the shape, area, and the like of the light emitting display region 202 are not particularly limited in addition to the above preferred embodiment.

  FIG. 3 is a block diagram showing a schematic configuration of the organic EL display device according to this embodiment. The organic EL display device 300 includes a mode for performing normal image display and a mode for functioning as a mirror with illumination. The organic EL panel 310 performs image display according to the drive voltage from the row electrode drive circuit 321 and the column electrode drive circuit 322, or functions as a mirror with illumination. The controller 331 controls switching between the image display mode and the mode that functions as an illuminated mirror. Since the image display mode is the same as the conventional technique, a mode that functions as a mirror with illumination will be described below.

  In the mode functioning as a mirror with illumination, the display area 311 of the organic EL panel 310 is divided into three divided display areas 312, 313, and 314, and the display is controlled for each divided display area. Some of the divided display areas are DC-driven, and the other divided display areas are not energized and are in a non-light emitting state. In the example of FIG. 3, the divided display area 312 functions as illumination by DC driving, and the other divided display areas 313 and 314 function as mirror surfaces in the non-light emitting state.

  A necessary voltage is supplied from the power supply circuit 332 to the row electrode driving circuit 321 and the column electrode driving circuit 322. Specifically, the row electrode drive circuit 321 is supplied with VH that is the non-selection voltage level of the row electrode and VSS that is the selection voltage level of the row electrode. Further, the column electrode drive circuit 322 is supplied with VD that is a column electrode selection voltage level and VSS that is a column electrode non-selection voltage level. VSS is a selection voltage level of the row electrode and a non-selection voltage level of the column electrode. In this example, the row electrode is a cathode and the column electrode is an anode.

  In the example of FIG. 3, the row electrode drive circuit 321 supplies the selection voltage level VSS to the divided display area 312. In addition, the row electrode drive circuit 321 supplies the non-selection voltage level VH to the divided display regions 313 and 314. The column electrode drive circuit 322 supplies the selection voltage level VD to all the divided display areas 312, 313, and 314. Since the output of the row electrode drive circuit 321 is at the non-selection voltage level VH, the divided display areas 313 and 314 are in a non-light emitting state.

  The controller 331 controls the switching between the image display mode and the specular mode and the selection of the light emitting area (selection of the non-light emitting area) in the specular mode according to an external command (Command). In the specular mode, the controller 331 supplies an enable signal (/ EN) to the row electrode drive circuit 321 and the column electrode drive circuit 322, and controls the output of the drive voltage. Each of the drive circuits 321 and 322 supplies a required drive voltage to the organic EL panel 310 when the enable signal (/ EN) is at the “enable” level, and when the enable signal (/ EN) is at the “disable” level. Is not supplied (the drive voltage is at a non-selection level).

  In addition, the controller 331 supplies a selection signal (Mux) to the row electrode drive circuit 321 in order to select a light emitting region that functions as illumination. The row electrode drive circuit 321 supplies the selection voltage level VSS to the divided display area specified by the selection signal (Mux), and supplies the non-selection voltage level VH to the other divided display areas. In order to select from three divided display areas, the selection signal (Mux) is composed of 2 bits. In this example, one divided display area selected from the three divided display areas functions as illumination by DC driving, but two or more divided display areas selected from the plurality of divided display areas are DC driven. Of course, it is possible.

  Next, the operation of the organic EL display device 300 of this embodiment will be described with reference to FIG. FIG. 4 is a timing chart showing an example of a change with respect to time of each signal in the display control of the organic EL display device. In FIG. 4, COM <b> 0 to COM <b> 2 indicate output numbers of the row electrode drive circuit 321. Each of COM0 to 2 corresponds to each of the divided display areas 312 to 314, and includes a row electrode corresponding to each divided display area. SEG indicates the output level of the column electrode drive circuit 322.

  First, an external command (Command) for requesting switching to the specular mode is input to the controller 331. The command includes an enable command for requesting that the output of each drive circuit be enabled, and a selection command for specifying a divided display area to be set in the light emission state. In response to an external command (Command), the controller 331 changes the enable signal (/ EN) to each of the drive circuits 321 and 322 from H level to L level and sets it to enable. In addition, a selection signal (Mux) is supplied to the row electrode driving circuit 321. In the example of FIG. 4, Mux (0) indicating that the divided display area 312 is selected is supplied.

  In response to the enable signal (/ EN) indicating that the output is turned ON and Mux (0) indicating that the output is selected, the row electrode driving circuit 321 outputs the selection voltage VSS to the divided display region 312. As shown in FIG. 4, the output of the row electrode specified by the output number COM0 changes from the non-selection voltage level (VH) to the selection voltage level (VSS). In the divided display areas 313 and 314, the output of the row electrode drive circuit 321 is maintained at the non-selected state VH. Therefore, the output of the row electrode specified by the output numbers COM1 and COM2 is maintained at VH.

  The column electrode drive circuit 322 outputs a selection voltage to the column electrodes in response to an enable signal (/ EN) indicating that the output is turned ON. As shown in FIG. 4, the output level (SEG) from the column electrode drive circuit 322 to the organic EL panel 310 changes from the non-selection voltage level (VSS) to the selection voltage level (VD). Thereby, the divided display area 312 is in a light emitting state, and the other divided display areas 313 and 314 are maintained in a non-light emitting state. The drive voltage to the divided display area 312 does not change with time and is driven by a DC voltage.

  Subsequently, after a predetermined time has elapsed, a new external command is input to the controller 331. The external command includes a selection command, and requests to change the light emitting area from COM0 (divided display area 312) to COM2 (divided display area 314). In response to the command, the controller 331 supplies a selection signal (Mux2) indicating selection of COM2 to the row electrode drive circuit 321. The row electrode drive circuit 321 changes the output level in response to the selection signal (Mux2).

  The output level of the row electrode included in COM0 is changed from the selection level (VSS) to the non-selection voltage level (VH), and the output level of the row electrode included in COM2 is changed from the non-selection voltage level (VH) to the selection voltage level (VSS). Change to). The output of COM1 is maintained at the non-selection voltage level (VH), and the output of the column electrode drive circuit 322 is maintained at the selection voltage level (VD). In this state, the divided display area 314 is in a light emitting state, and the other divided display areas 312 and 313 are in a non-light emitting state.

  Subsequently, an external command for stopping the mirror mode is input to the controller 331. The external command includes a command for requesting that the output of each drive circuit be disabled (disabled). In response to the input external command, the controller 331 changes the enable signal (/ EN) to each of the drive circuits 321 and 322 from L level (enable) to H level (disable).

  The row electrode drive circuit 321 changes the output to the organic EL panel 310 in response to the change of the enable signal (/ EN). Specifically, the output of COM2 changes from the selected voltage level (VSS) to the non-selected voltage level (VH). Similarly, the column electrode drive circuit 322 changes the output level from the selection voltage level (VD) to the non-selection voltage level (VSS). As a result, the entire display area 311 enters a non-light emitting state.

  As described above, according to the present embodiment, since the organic EL display device includes the image display mode and the mirror surface mode, these can be effectively switched and used as required by the user. Alternatively, when the organic EL display device functions as a mirror, since a part of the display area is used as illumination, the contrast of the reflected image by the mirror surface can be improved. Moreover, since the display area which functions as illumination can be selectively switched, the illumination effect can be changed according to the situation.

  In the present embodiment, the organic EL display device has a mode in which an image is displayed, but an illumination mode that functions as an illumination instead of an image display can be provided. For example, in the illumination mode, all display areas are in a light emitting state by DC driving. In the above example, for example, by assigning the selection signal (Mux3) to the illumination mode, the mode can be switched with a simple configuration. In this example, a display area composed of a plurality of pixels is used. However, in order to function as a mirror with illumination, the light emitting display area and the non-light emitting display area need to be composed of a plurality of pixels. There is no.

  The organic EL display device of the present invention can use a top emission type organic EL display device in addition to the bottom emission type exemplified above.

It is sectional drawing which shows schematic structure of the organic EL light emitting element in this embodiment. It is a figure which shows the example of the preferable display state of a display area in the case of using the organic electroluminescent display apparatus in this embodiment as a mirror. It is a block diagram which shows schematic structure of the organic electroluminescent display apparatus in this embodiment. It is a timing chart which shows an example of change with respect to time of each signal in display control of an organic electroluminescence display in this embodiment.

Explanation of symbols

100 organic EL light emitting device, 101 glass substrate, 102 anode,
103 organic EL layer, 104 cathode, 105 sealing substrate, 106 water-absorbing agent,
200 display area, 201 non-light emitting display area, 202 light emitting display area,
300 organic EL display device, 310 organic EL panel, 311 display area,
312 split display area, 313 split display area, 314 split display area,
321 row electrode drive circuit, 322 column electrode drive circuit,
331 controller, 332 power circuit

Claims (6)

An organic EL device having a light emitting region that emits light by supplying a driving current to an organic light emitting layer through an internal metal layer, wherein the light emitting region is
A mirror surface region that is switched between a light emitting state and a non-light emitting state, and functions as a mirror by specularly reflecting external light by the internal metal layer in the non-light emitting state;
An illumination region that emits illumination light by DC driving the organic light emitting layer;
An organic EL device having The organic EL device includes a first mode for displaying an image and a second mode that functions as a mirror.
The mirror surface area displays an image in the first mode, functions as a mirror by specular reflection in the second mode,
The illumination area performs image display in the first mode and emits illumination light in the second mode.
The organic EL device according to claim 1. The light emitting area is composed of a plurality of divided areas,
A part of the plurality of divided areas emits illumination light by DC driving,
Other regions of the plurality of divided regions function as mirrors by specularly reflecting external light in the internal metal layer,
The organic EL device according to claim 1 or 2.   The organic EL device according to claim 3, further comprising a controller that selects the illumination area and the mirror area from the plurality of divided areas. The light emitting region is defined by a plurality of first electrode wiring layers arranged in a first direction and a plurality of second electrode wiring layers arranged so as to overlap the plurality of first electrode wiring layers. ,
The illumination area is defined by all of the plurality of second electrode wiring layers and the part of the first electrode wiring layers arranged in succession.
The organic EL device according to claim 1. The organic EL device includes a first mode that functions as illumination, and a second mode that functions as a mirror,
The specular region radiates illumination light by DC driving in the first mode, and functions as a mirror by specular reflection in the second mode,
The illumination area emits illumination light by DC driving in the first and second modes.
The organic EL device according to claim 1.

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