JP2006259307A - Display device and imaging apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device with excellent service life characteristics capable of stable display on both display surfaces even when an element structure has low heat resistance in a dual-emission display means. <P>SOLUTION: A heat radiating body 42 is arranged in an area corresponding to a part between respective pixels 47 on the side of the display surface 52 and heat generated from respective organic EL element 40 is discharged. On the dual-emission organic EL panel 41, the heat is radiated from the organic EL panel 41 without obstructing the display of video images on both display surfaces 51 and 52. Thus, the temperature rise of the organic EL elements 40 is suppressed while maintaining excellent video display. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a display device having first and second display surfaces facing each other, and an imaging device having such display means.

  Video cameras and digital still cameras equipped with a display means such as a monitor are generally provided with a face-to-face shooting mode that allows the subject to recognize the image at the time of imaging, and the display means is directed to the subject side. It is realized with. Further, a liquid crystal display device is generally used as a display means in these devices.

  However, since this liquid crystal display device is a single-sided light emitting display device, in such a face-to-face shooting mode, if the photographer himself is not a subject, there will be another way for the photographer to recognize the subject image. Display means are required. Therefore, conventionally, the viewfinder provided in these devices is turned on, and the subject image is recognized when the photographer looks into the viewfinder.

  As other display means other than the liquid crystal display device, an organic EL display device using an organic EL (ElectroLuminescence) element is conceivable. An organic EL element is a light emitting element in which an organic layer is laminated between an anode and a cathode. An organic EL display device in which a plurality of organic EL elements are arranged is promising as a next-generation flat panel display that replaces a liquid crystal display device. Is being viewed.

  Here, this organic EL display device is also basically a single-sided light emitting display device. Examples of the single-side light emission method include a top emission method (top emission) method and a bottom emission method (bottom emission). The difference in the element structure in these light emitting systems is that which of the anode and the cathode is made of a light transmissive material.

  Recently, a double-sided light emitting type that combines these top side light emitting method and bottom surface emitting method has also been developed. For example, in Patent Document 1, in an organic EL element in which an organic layer is laminated between an opaque cathode electrode (cathode) and a transparent anode electrode (anode), a transparent light guide is formed on a part of the opaque cathode electrode. A double-sided light emitting organic EL display device as described above is disclosed.

By using such a dual emission organic EL display device, a subject image can be displayed simultaneously on the subject side and the photographer side, and a face-to-face shooting mode can be realized conveniently. In addition, since each pixel is configured to be shared by both display surfaces, there is an advantage that a horizontally reversed video that is easy to recognize for the subject side is displayed on the subject side without performing image processing or the like. .
JP 2001-332392 A

  By the way, since the organic EL element is a light-emitting element driven by current, the current consumption increases as compared with a liquid crystal element that is a display element driven by voltage, and heat generation in the light-emitting region increases. In the organic EL element, deterioration of the organic layer constituting the element is accelerated by the temperature rise caused by the heat generation. For this reason, the luminance of each organic EL element is lowered, the luminance difference is partially generated, the display is uneven, the light emission is unstable, and the stability with time is low and the lifetime is short. There was a problem.

  Therefore, in an organic EL display device including such an organic EL element, it is necessary to sufficiently consider heat dissipation and prevent a temperature increase in each organic EL element. Conventionally, in a single-sided organic EL display device, a heat dissipation mechanism that suppresses such a temperature rise is arranged on the side opposite to the display surface.

  However, since the double-sided light emitting organic EL display device has a structure having two display surfaces facing each other, a heat dissipation mechanism is disposed at such a position without hindering image display on one display surface. It is not possible. Therefore, in the past, as a countermeasure for the temperature rise of the element, it was only possible to cool the outside air directly, and it was not possible to take a sufficient heat radiation countermeasure while maintaining good display on both display surfaces.

  On the other hand, the organic EL element has a problem in that the power consumption becomes larger than that of the liquid crystal element because the luminous efficiency is not sufficient. Therefore, conventionally, in a single-sided organic EL display device, a reflector is disposed on the side opposite to the display surface to increase luminous efficiency and improve luminance, thereby suppressing power consumption. However, in a double-sided light emitting organic EL display device, a reflector cannot be disposed at such a position due to its structure. Therefore, the luminous efficiency is reduced and the luminance is also lowered. To ensure the visibility of the displayed image, the luminance is improved by increasing the current flowing to the organic EL element than that of the single-sided emission type. Need to be made.

  However, when the current passed through the organic EL element is increased as described above, the deterioration of the element due to the heat generation as described above is further increased. Therefore, the double-sided light emitting type organic EL display device needs to take more heat radiation measures than the single-sided light emitting type.

  Thus, in the conventional double-sided light emitting organic EL display device that cannot take sufficient heat dissipation measures while maintaining good display on both display surfaces, a display device capable of stable display and good life characteristics It was difficult to get.

  As a countermeasure, it is conceivable that the structure of the element itself can withstand the temperature rise. However, since there is no material with high luminous efficiency and high heat resistance at present, there is a problem that development takes a considerable period of time and cost.

  The present invention has been made in view of such problems, and its purpose is to enable stable display on both display surfaces even if the element structure has low heat resistance in a double-sided light emitting display means. It is another object of the present invention to provide a display device having good lifetime characteristics and an imaging device including such a display means.

  A display device according to the present invention includes a display panel including a plurality of light emitting elements having first and second display surfaces facing each other and constituting each pixel, and at least one of the first and second display surfaces. A heat dissipating body that is disposed in a region corresponding to the area between the pixels on one surface side and that releases heat generated from the light emitting element is provided.

  An image pickup apparatus according to the present invention includes an image pickup unit that picks up a subject and a display unit that displays a subject image picked up by the image pickup unit. The display unit includes first and second display surfaces facing each other. And a display panel including a plurality of light emitting elements constituting each pixel, and disposed in a region corresponding to the above pixels on at least one of the first and second display surfaces. And a radiator that releases the generated heat.

  In the display device and the imaging device of the present invention, an image based on the light emitted from each light emitting element is displayed on the first and second display surfaces. In addition, since the heat radiating body is arranged on at least one of these display surfaces, heat generated from each light emitting element is released. Since this heat radiating body is also arranged in a region corresponding to between the pixels formed by each light emitting element, the emitted light from each light emitting element is emitted without being blocked by the heat radiating body. That is, heat is dissipated from the display panel without hindering the display of images on both display surfaces.

  According to the display device or the imaging device of the present invention, the heat radiator is arranged in a region corresponding to between the pixels, and the heat generated from each light emitting element is released. Heat can be radiated from the display panel without hindering, and temperature rise of the light emitting element can be suppressed while maintaining a good video display. Therefore, it is possible to prevent the deterioration of the light emitting element due to the temperature rise due to heat generation and improve the reliability, so that it is possible to obtain a display means capable of stable display on both display surfaces and having good life characteristics. Can do.

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

[First Embodiment]
FIG. 1 shows a shooting situation of a subject 8 by the imaging apparatus (video camera 1) according to the first embodiment of the present invention. The face-to-face enables recognition of a video even on the subject 8 side during imaging. This shows a situation in which the subject image P1 is displayed on the display surface 51 of the display unit 4 using the photographing mode. 2A and 2B show the situation of the video camera 1 as viewed from the subject 8 side in FIG. 1 (in the direction of the line of sight of the arrow X shown in FIGS. 1 and 2). .

  The video camera 1 includes a main body 2, a lens unit 3 that images a subject 8, a display unit 4 that can be opened and closed in a direction indicated by an arrow Y, a viewfinder 6 that can observe a subject image, and a battery pack 7. It has. Here, the lens unit 3 corresponds to a specific example of “imaging unit” in the present invention, and the display unit 4 corresponds to a specific example of “display device” and “display unit” in the present invention.

  The display unit 4 displays a video (for example, a subject image P1) at the time of imaging on the display surface 51 and a video that has already been captured, and functions as a monitor in the video camera 1. As will be described later, the display unit 4 includes an active matrix organic EL panel 41 in which pixels formed by a plurality of organic EL elements 40 are arranged in a matrix.

  In addition to the display surface 51 on the photographer side, the display unit 4 has a display surface 52 on the subject 8 side facing the display surface 51, as shown in FIG. An image (for example, a subject image P2) is also displayed on the display surface 52. That is, the display unit 4 is a double-sided light emitting type capable of displaying an image on both the display surface 51 and the display surface 52. As will be described later, the display unit 4 has a double-sided display state in which video is displayed on the display units 51 and 52 and a single-sided display state in which video is displayed only on the display unit 51.

  In this way, the photographer and the subject 8 can take an image using the face-to-face shooting mode by using the display surfaces 51 and 52 in the double-sided display state. As will be described later, in the organic EL element 40, since the pixels constituting both the display surfaces 51 and 52 are configured to be shared by both the display surfaces 51 and 52, the display surface on the subject 8 side. The image 52 is displayed on the subject 8 side so that it can be easily recognized without being subjected to image processing or the like (for example, the subject image P2 is horizontally reversed with respect to the subject image P1). Yes.

  As will be described in detail later, as shown in FIG. 2B, the video camera 1 is also provided with a normal shooting mode for displaying an image only on the display surface 51 on the photographer side at the time of shooting. Yes. In this normal photographing mode, an image is displayed only on the display surface 51 (single-sided display state). In this way, the photographer can arbitrarily select a face-to-face shooting mode in which an image is displayed on the display surfaces 51 and 52 and a normal shooting mode in which an image is displayed only on the display surface 51 during imaging.

  The video camera 1 can store captured images in a storage unit (not shown). As this storage means, for example, a storage medium (semiconductor memory or the like) built in the video camera 1, a removable storage medium (semiconductor memory card, recordable DVD (Digital Versatile Disc), or recordable CD (Compact Disc) )) And the like. The video camera 1 can reproduce the captured video stored in the storage means and display it on the display unit 4. Note that the video to be reproduced is not limited to the video taken by the photographer himself, but may be a video stored by another means. It also plays back and displays captured video stored in external storage means (PC (Personal Computer), etc.) via a wired or wireless interface (USB (Universal Serial Bus), wireless LAN (Local Area Network), etc.) not shown. It is also possible to display on the part 4.

  The display surfaces 51 and 52 correspond to specific examples of “first display surface” and “second display surface” in the present invention, respectively.

  FIG. 3 schematically shows a cross-sectional configuration of the display unit 4, and corresponds to a cross-sectional view taken along the line AA in FIG. 1. The display unit 4 includes an organic EL panel 41, a plurality of heat dissipating bodies 42 provided on the back surface of the organic EL panel 41, a heat conductive sheet 43 provided so as to cover the heat dissipating body 42, and an organic EL panel The heat dissipating bodies 44A and 44B are provided at both ends of the 41, respectively.

  The organic EL panel 41 is of the double-sided emission type as described above, and the upper surface emission light L1 and the lower surface emission light L2 are emitted from the display surfaces 51 and 52 in the display area D, respectively. The organic EL panel 4 corresponds to a specific example of “display panel” in the present invention. The heat radiator 42 emits heat generated from each organic EL element, and is provided in a region corresponding to each pixel of the organic EL panel 41. The heat conductive sheet 43 conducts heat released from the heat radiating body 42 to the heat dissipating bodies 44A and 44B. Details of the radiator 42 and the heat conductive sheet 43 will be described later.

  Each of the heat radiating bodies 44A and 44B is thermally connected to the heat radiating body 42 via the heat conducting sheet 43, and radiates the heat conducted from the heat radiating body 42 to the outside of the organic EL panel 41. is there. The heat dissipating bodies 44A and 44B are made of, for example, a metal or resin having excellent heat conductivity.

  Next, with reference to FIG. 4, the detail of the cross-sectional structure of the organic electroluminescent panel 41, the heat radiator 42, and the heat conductive sheet 43 is demonstrated. FIG. 4 shows an example of these cross-sectional configurations.

  The organic EL panel 41 has a laminated structure in which a multilayer film is formed on a glass substrate 401. Specifically, the multilayer film includes a gate electrode 402, a gate insulating layer 403, a p-Si (poly-silicon) layer 404, an insulating layer 405, a wiring 406, a source (drain) from the glass substrate 401 side. ) An electrode 407, a planarizing layer 408, a contact portion 409, an anode electrode 410, a light emitting layer 411 made of an organic material, a cathode electrode 412, a partition wall 413, a protective layer 414, and a transparent seal 415. Has been. Here, the glass substrate 401 corresponds to a specific example of “transparent substrate” in the present invention, and the protective layer 414 and the transparent seal 415 correspond to a specific example of “protective layer” in the present invention.

  Of these, the organic EL element 40 is configured by the anode electrode 410, the light emitting layer 411, and the cathode electrode 412. The organic EL element 40 corresponds to a specific example of “light emitting element” in the present invention.

  The glass substrate 401 is a substrate for stacking the multilayer films as described above. However, as long as it can transmit the bottom emission light L <b> 2 from the organic EL element 40, it may be constituted by a light-transmitting plastic substrate, for example.

  The gate electrode 402, the gate insulating layer 403, the p-Si layer 404, the insulating layer 405, the wiring layer 406, and the source (drain) electrode 407 constitute a switching element S for driving each organic EL element 40 to emit light. . The switching element S is composed of, for example, a thin film transistor (TFT). In addition, the wiring 406 includes, for example, signal lines and data lines for driving each organic EL element 40, and is connected to a driving circuit of the organic EL panel 41 (not shown). The switching element S and the wiring 406 are both disposed in a region corresponding to each pixel, and are electrically connected to the anode electrode 410 of each organic EL element 40 through a contact portion 409.

The planarization layer 408 is made of an insulating material such as silicon oxide (SiO ₂ ), for example, and covers and planarizes the switching elements S and the wirings 406 described above. The anode electrode 410 and the cathode electrode 412 function as an anode and a cathode in the organic EL element 40, respectively. The anode electrode 410 is electrically connected to the switching element S and the wiring 406 via the contact portion 409 as described above, while the cathode electrode 412 functions as a common electrode for each pixel. Since the organic EL panel 41 is of a double-sided emission type as described above, the anode electrode 410 and the cathode electrode 412 are both transparent materials such as ITO (Indium Tin Oxide), or Constructed from translucent material.

  The light emitting layer 411 is formed by depositing a layer made of an organic material and has a structure sandwiched between the anode (anode electrode 410) and the cathode (cathode electrode 412) as described above. Then, by applying a forward bias voltage between the anode and the cathode, holes and electrons are injected into the light emitting layer from the anode and the cathode, respectively, and light emission is obtained by the recombination of the injected positive and negative carriers. (For example, the upper surface outgoing light L1 and the lower surface outgoing light L2 in the figure).

The partition 413 is for separating each pixel and is made of an insulating material such as silicon oxide (SiO ₂ ). The protective layer 414 and the transparent seal 415 are for protecting the surface of the organic EL panel 41 and sealing each organic EL element from the outside to prevent moisture from entering. The protective layer 414 is made of an insulating material such as silicon oxide (SiO ₂ ), and the transparent seal 415 is made of a transparent material.

  Here, in the display unit 4 of the present embodiment, as described above, the radiator 42 and the heat conductive sheet 43 are provided on the back surface of the glass substrate 401, that is, on the display surface 52 side, and are generated from each organic EL element 40. Heat can be released. The heat conductive sheet 43 also plays a role of flattening the heat radiator 42.

  FIG. 5 schematically shows the positional relationship between the radiator 42 and each pixel 47 in which the organic EL element 40 is arranged, in a plan view from the display surface 52 side of the organic EL panel 41. Thus, the heat radiator 42 is disposed in a corresponding region between the pixels 47 on the display surface 52 side. Further, since the pixels 47 are arranged in a matrix, the heat radiator 42 is arranged in a grid corresponding to the arrangement of the pixels 47. Accordingly, even in the double-sided display state (upper surface outgoing light L1 and lower surface outgoing light L2 are emitted) as shown in FIG. 4, the outgoing light (lower surface outgoing light L2) to the display surface 52 side is hindered. There is no. For example, in the cross-sectional configuration shown in FIG. 4, the region corresponding to each pixel 47 on the display surface 52 side is a region corresponding to the switching element S or the wiring 406 on the back surface of the glass substrate 401.

  The radiator 42 is made of a metal or resin having excellent thermal conductivity, or a combination thereof, and can efficiently release the heat generated from each organic EL element 40. Examples of such a metal material include Al (aluminum), an Al alloy, and Cu (copper). Examples of such a resin material include graphite.

  Further, as shown in FIG. 4, a light reflecting layer 45 having a light reflecting function is formed on the surface of the heat radiating body 42 on the organic EL panel 41 side. The light reflecting layer 45 is made of a highly reflective metal, resin, or a combination thereof, and efficiently reflects the bottom emission light L2 from each organic EL element 40 in a single-sided display state as will be described later. It can be done. Examples of such a metal material include Al (aluminum), an Al alloy, and Cu (copper). Moreover, it is preferable that the material which comprises this light reflection layer 45 is an achromatic thing. This is because it is possible to prevent the reflected light from becoming colored when reflecting the bottom emission light L2 as described above.

Specific examples of the combination of the radiator 42 and the light reflection layer 45 include the following (A) to (D).
(A) a metal having excellent thermal conductivity such as Cu (heat radiating body 42), and a metal having a reflective color such as Al or Al alloy that is as achromatic as possible and having excellent thermal conductivity (light reflecting layer 45); (B) A combination of a metal having excellent thermal conductivity such as Cu (heat radiating body 42) and a resin material (light reflecting layer 45) having a reflection color that is as achromatic as possible and having excellent thermal conductivity ( C) Combination of a resin material excellent in thermal conductivity (heat radiating body 42) and a resin material (light reflecting layer 45) in which the reflection color is as achromatic as possible and excellent in thermal conductivity (D) Thermal conductivity Combination of an excellent resin material (heat radiating body 42) and a metal (light reflecting layer 45) having a reflective color such as Al or Al alloy that is as achromatic as possible and excellent in thermal conductivity

  The heat radiator 42 and the light reflecting layer 45 can be formed by, for example, bonding, plating, coating, or the like. Further, instead of forming such a light reflecting layer 45 on the radiator 42, the radiator 42 itself may have a light reflecting function.

  On the other hand, the heat conductive sheet 43 is composed of, for example, air, silicon oil, resin, etc., and efficiently conducts heat released from the heat radiating body 42 to the heat radiating bodies 44A and 44B, and slides the heat radiating body 42 described later. On the other hand, it can be smoothly deformed.

  Further, as shown in FIG. 4, a surface protective sheet 46 is further provided on the heat conductive sheet 43 on the display surface 52 side of the organic EL panel 41. The surface protection sheet 46 is for protecting the heat radiator 42 and the heat conductive sheet 43 from the outside. In addition, you may make it comprise this surface protection sheet 46 with the polarizing plate which permeate | transmits only the light polarized in the specific direction, for example. In such a configuration, it is possible to more sufficiently prevent the lower surface emission light L2 from leaking to the display surface 52 side in the single-sided display state as will be described later.

  Since the heat conductive sheet 43 and the surface protective sheet 46 transmit the bottom emission light L2, the material constituting them may be an achromatic color similar to the light reflecting layer 45 described above. preferable.

  Here, as shown in FIG. 6, the heat radiating body 42 is configured to be slidable in the extending surface direction (in-plane direction of the display surface 52). For example, when the organic EL panel 41 is set in a double-sided display state (the upper surface emission light L1 and the lower surface emission light L2 are emitted) by the switching unit 48 described later, the heat radiator 42 is slid and housed between the pixels 47. When the organic EL panel 41 is set in a single-sided display state (only the top emission light L1 is emitted), the radiator 42 is slid. It is developed and arranged in an area corresponding to each pixel 47 (arrangement in FIG. 6). Thus, the double-sided display state and the single-sided display state of the organic EL panel 41 are switched. It should be noted that only the top emission light L1 is set to be emitted in the single-sided display state, as shown in FIGS. 4 and 6, on the display surface 52 side, such as the switching element S and the wiring 406. This is because the aperture ratio on the display surface 51 side can be made larger than that on the display surface 52 side. Moreover, since the frequency of use is lower in the face-to-face shooting mode, the luminance on the display surface side used in the normal shooting mode can be improved.

  Further, as described above, the light reflecting layer 45 is formed on the surface of the heat radiating body 42 on the organic EL panel 41 side, so that the bottom emission light L2 is emitted in the single-sided display state as shown in FIG. Reflected by the reflective layer 45 and emitted toward the display surface 51 side. Therefore, both the upper surface emitted light L1 and the lower surface emitted light L2 from each organic EL element 40 are emitted to the display surface 51 side, and the light emission efficiency is improved.

  Further, as shown in FIGS. 7A and 7B, in the video camera 1 according to the present embodiment, the slide drive for the heat radiating body 42 is provided in, for example, the video camera 1 or the display unit 4. You may comprise so that it may control by the microcomputer 22 grade | etc.,. 7A and 7B schematically show the organic EL panel 41 viewed from the display unit 52 side, and FIG. 7A shows a case where the organic EL panel 41 is in a double-sided display state. , (B) show cases where the organic EL panel 41 is in a single-sided display state.

  In the configuration of FIG. 7, for example, when the photographer operates, for example, via the operation unit 21 provided in the video camera 1, the microcomputer 22 controls the switching unit 48 to drive the radiator 42 (FIG. 7B). The movement operation in the Z direction shown in FIG. 6 is performed by a control signal 221 from the microcomputer 22. Thus, by controlling the driving operation of the switching unit 48 by the microcomputer 22, the photographer can conveniently switch between the double-sided display state and the single-sided display state.

  Next, processing for determining each mode in the video camera 1 having such a configuration will be described with reference to FIGS. 8 to 10 show each mode determination process, and FIG. 11 shows an example of a display state on the display unit 4.

  The video camera 1 has a shooting mode for shooting and a playback mode for playing back the stored video. In the video camera 1, the display state (display mode) of the display unit 4 changes variously according to the open / closed state of the display unit 4 and the difference in the shooting / playback mode. As the display modes, there are a double-sided display mode (double-sided display state) and a single-sided display mode (single-sided display state) as described above. Therefore, the process for determining the photographing mode or the reproduction mode here also means the process for determining the double-sided display mode or the single-sided display mode of the organic EL panel 41.

  First, the photographer selects which of the photographing mode and the reproduction mode is to be used by using the operation unit 21 described above (step S11 in FIG. 8). When the shooting mode is selected (step S11: “shooting mode”), next, a shooting mode determination process is performed to select a specific shooting mode to be used (step S12). On the other hand, when the reproduction mode is selected (step S11: “reproduction mode”), a reproduction mode determination process for selecting a specific reproduction mode to be used is performed (step S13).

  In the shooting mode determination process, first, the photographer uses the operation unit 21 or the like to select whether to use the display unit 4 in an open state or in a closed state (step S121 in FIG. 9). When it is selected to use in the closed state (step S121: N), the display of the video on the display unit 4 is turned off on both the display surfaces 51 and 52 (step S122). At this time, for example, the display of the subject image in the viewfinder 6 is turned on, and the photographer uses the viewfinder 6 instead of the display unit 4 to capture the subject image.

  On the other hand, in step S121, when it is selected that the display unit 4 is used in an opened state (step S121: Y), the display on the display surface 51 (the photographer side display surface) in the display unit 4 is turned on. (Step S123). At this time, for example, the display of the subject image in the viewfinder 6 is turned off. Next, the photographer selects whether or not to slide the radiator 42 using the operation unit 21 or the like (step S124). If it is selected not to move the slide (step S124: N), the radiator 42 remains arranged in the area corresponding to each pixel 47, so the display unit 4 is also in the single-sided display mode with only the display surface 51 as it is. The video camera 1 enters the normal shooting mode (step S125). As a method of slidingly driving the heat radiating body 42 as described above, it may be controlled by the microcomputer 22 as described above, or manually by the photographer.

  On the other hand, when it is selected in step S124 that the radiator 42 is slid (step S124: Y), the switching unit 48 moves the radiator 42 to a region corresponding to each pixel 47 (step S126). Therefore, the display unit 4 is in a double-sided display mode in which video is displayed on the display surfaces 51 and 52, and the video camera 1 is in a face-to-face shooting mode (step S127). In the face-to-face shooting mode, as described above, a horizontally reversed video is displayed on the display surface 52 on the subject 8 side without performing any particular image processing. In this way, specific mode determination processing (duplex display mode or single-side display mode determination processing) in the shooting mode is performed, and the entire mode determination processing ends.

  On the other hand, also in the reproduction mode determination process, first, the photographer selects whether to use the display unit 4 in the opened state or the closed state by using the operation unit 21 (step S131 in FIG. 10). When it is selected to use in the open state (step S131: Y), the display on the display surface 51 is turned on (step S132) as in the case of the above-described shooting mode determination process. At this time, for example, the display of the subject image in the viewfinder 6 is turned off. Next, the photographer selects whether or not to slide the radiator 42 (step S133). When the photographer chooses not to move the slide (step S133: N), as described above, only the display surface 51 is selected. The single side display mode is set, and the video camera 1 is set to the normal playback mode A (step S134). On the other hand, when it is selected to slide the radiator 42 (step S133: Y), the switching unit 48 moves the radiator 42 as described above (step S135), so that the display surfaces 51 and 52 are moved. A double-sided display mode in which video is displayed is entered, and the video camera 1 enters a face-to-face playback mode (step S136).

  On the other hand, if it is selected in step S131 that the display unit 4 is used in a closed state (step S131: N), then the photographer also selects whether or not to slide the radiator 42 (step S131). S137). When the slide movement is selected (step S137: Y), the display on the display surface 52 is turned on (step S138), and the switching unit 48 moves the radiator 42 as described above (step S139). For example, the normal reproduction mode B as shown in FIG. 11A is set (step S140). In addition, at this time, it is a double-sided display mode in which an image is displayed on the display surfaces 51 and 52, and an image is also displayed on the display surface 51 side (not shown). Also, in the normal playback mode B, unlike the above-described face-to-face shooting mode, a video image that is horizontally reversed by image processing (that is, a video image in the original state) is displayed on the display surface 52. On the other hand, when it is selected not to slide the radiator 42 in step S137 (step S137: N), for example, as shown in FIG. Both 51 and 52 are turned off (step S141). Also at this time, for example, video display in the viewfinder 6 is turned on. In this way, specific mode determination processing (duplex display mode or single-side display mode determination processing) in the playback mode is performed, and the entire mode determination processing ends.

  As described above, according to the present embodiment, the heat dissipating body 42 is disposed in the region corresponding to the area between the pixels 47 on the display surface 52 side, and the heat generated from each organic EL element 40 is released. Even in the double-sided light emitting type organic EL panel 41, it is possible to dissipate heat from the organic EL panel 41 without interfering with the display of the images on both the display surfaces 51 and 52, and the organic EL while maintaining a good image display. The temperature rise of the element 40 can be suppressed. Therefore, it is possible to prevent the deterioration of the organic EL element 40 due to the temperature rise due to heat generation and improve the reliability. Therefore, stable display on both the display surfaces 51 and 52 is possible, and the life characteristics are good. Display means (display unit 4) can be obtained.

  In addition, since the heat released from each radiator 42 is dissipated to the outside by the heat dissipating bodies 44A and 44B via the heat conducting sheet 43, heat generation in the entire organic EL panel 4 can be suppressed. . Therefore, a partial heat generation imbalance state in the display region D of the organic EL panel 41 can be suppressed, and unevenness in the display image can be suppressed.

  Further, since the heat radiating body 42 is slid by the switching unit 48, a single-sided display state can be configured in the double-sided light emitting organic EL panel 41, and the lower surface emission light L2 leaks to the display surface 52 side. Can be prevented. For example, when the surface protection sheet 46 is formed of a polarizing plate, the leakage of the bottom emission light L2 can be completely prevented.

  In addition, since the light reflecting layer 45 is formed on the surface of the radiator 42 on the organic EL panel 41 side (or so that the radiator 42 itself has a light reflecting function), the bottom surface is projected in the single-sided display state. The incident light L2 can be reflected and emitted to the display surface 51 side, and the luminous efficiency can be improved. Therefore, since the light emission luminance can be increased, the light emission luminance can be ensured even with a lower current, and the power consumption can be reduced. Further, since the current flowing to the organic EL element 40 can be reduced, the deterioration of the element can be further suppressed, and the life can be further extended.

  Furthermore, since the heat dissipation mechanism composed of the heat dissipating body 42, the heat conductive sheet 43, and the heat dissipating bodies 44A and 44B can be arranged outside the organic EL panel 41, the conventional organic EL panel can be used. Can also be formed easily.

[Second Embodiment]
Next, a second embodiment of the present invention will be described. The imaging apparatus (video camera 1) of the present embodiment is basically the same as the video camera 1 of the first embodiment, and differs from the first embodiment in that heat is dissipated in the organic EL panel 41. This is the configuration of the body 42. Therefore, the description of the entire configuration of the video camera 1 (corresponding to FIG. 1 in the first embodiment) and the entire configuration of the display unit 4 (corresponding to FIG. 3 in the first embodiment) is omitted. To do.

  FIG. 12 illustrates a cross-sectional configuration of the organic EL panel 41, the heat radiator, and the heat conductive sheet 43 according to the present embodiment, and corresponds to FIG. 4 in the first embodiment. In this figure, the same components as those in the first embodiment shown in FIG. 4 are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

  The heat dissipating body of the present embodiment has a multi-stage structure of the heat dissipating body 42 in the first embodiment, and specifically has a two-stage configuration (heat dissipating bodies 42A and 42B). In addition, light reflecting layers 45A and 45B are formed on the surfaces of the heat dissipating bodies 42A and 42B on the organic EL panel 41 side, respectively, similarly to the heat dissipating body 42 in the first embodiment. Further, similarly to the first embodiment, for example, as shown in FIG. 13, the heat radiating bodies 42 </ b> A and 42 </ b> B (and the light reflecting layers 45 </ b> A and 45 </ b> B) are respectively provided in the extending surface direction by the switching unit 48. It can be slid independently.

  In the display unit 4, the heat radiating bodies 42 </ b> A and 42 </ b> B are independently slid and driven by the switching unit 48, and are arranged in regions corresponding to the pixels 47, whereby the organic EL panel 41 is in a single-sided display state. At this time, since the heat radiating body has a two-stage structure, the area of the region where the heat radiating bodies 42A and 42B block the bottom emission light L2 becomes larger than in the case of the one-stage configuration in the first embodiment. On the other hand, when the area is approximately the same as that in the single-stage configuration, the area between the pixels 47 is narrowed.

  As described above, according to the present embodiment, since the heat radiator has a two-stage structure (heat radiators 42A and 42B), it is possible to increase the area of the region that blocks the bottom emission light L2 in the single-sided display state. In addition to the effects of the first embodiment, it is possible to further prevent the lower surface emission light L2 from leaking to the display surface 52 side.

  On the contrary, when the area of the area where the lower surface emission light L2 is blocked by the heat radiating bodies 42A and 42B is set to the same area as that of the one-stage configuration, the area between the pixels 47 is narrowed. Thus, the aperture ratio of the organic EL panel 41 can be increased. Therefore, the light emission luminance of the display unit 4 can be improved.

  In the example shown in FIGS. 12 and 13, the heat radiating body has a two-stage configuration. However, the structure of the heat radiating body is not limited to this, and for example, an arbitrary structure having three or more stages can be used. is there.

  Although the present invention has been described with reference to the first and second embodiments, the present invention is not limited to these embodiments, and various modifications can be made.

  For example, in the above embodiment, as shown in FIG. 5, for example, the pixels 47 formed by the organic EL elements 40 are arranged in a matrix, and the radiators 42 are also arranged in a grid according to the pixels. Although the example has been described, the arrangement of the radiators 42 is not limited to the lattice shape. For example, as shown in FIGS. 14A and 14B, the vertical line direction or horizontal line between the pixels 47 is shown. You may comprise so that it may arrange | position along only any one of directions.

  At this time, it is preferable that the region corresponding to each pixel 47 is disposed along only a wider direction in the vertical line direction and the horizontal line direction. When arranged in such a manner, the effect of radiating heat can be further enhanced as compared with the case where the arrangement is made along only a narrower direction. For the same reason, for example, as shown in FIG. 14C, in the case where the radiators 42 are arranged in a lattice shape, the region corresponding to each pixel 47 is wider (in this case, the horizontal line direction). It is preferable that the width of the portion along the line is made wider than the width of the portion along the narrower direction (in this case, the vertical line direction).

  Moreover, in the said embodiment, although the example at the time of arrange | positioning the heat radiator 42 in the display surface 52 side in the organic electroluminescent panel 41 was demonstrated, for example, as shown in FIG. A heat radiating body (heat radiating body 49) may also be arranged on the surface 51 side, or only the heat radiating body 49 may be arranged instead of the heat radiating body 42. When the heat dissipating bodies 42 and 49 are arranged on both display surfaces of the display surfaces 51 and 52, the deterioration of the elements is further suppressed by further suppressing the temperature rise in each organic EL element 40, thereby extending the life. Can be achieved. For example, in the case of the cross-sectional configuration shown in FIG. 15, the region corresponding to each pixel 47 on the display surface 51 side is a region corresponding to the partition wall 413 on the surface of the transparent sheet 415.

  In the above embodiment, an example has been described in which the organic EL panel 41 emits light from the top (when only the top emission light L1 is emitted) when the display is in the single-sided display state. It may be configured to emit lower surface light (only the lower surface light L2 is emitted), and when the radiator is arranged on both display surfaces of the display surfaces 51 and 52 as described above, Further, it may be configured to switch between the case of top emission and the case of bottom emission according to the usage status of the reproduction mode.

  In addition, the materials and configurations of the components described in the above embodiment are not limited, and may be other materials or other configurations.

  In the above embodiment, the configuration of the video camera 1, the display unit 4, and the organic EL panel 41 is specifically described. However, it is not necessary to include all the components or all the layers. Components or other layers may be provided.

  Furthermore, the light-emitting element to which the present invention is applied is not limited to an organic EL element, and can be applied to all display devices having a light-emitting element that preferably prevents deterioration of the element due to heat generation. is there. In this case, the pixels 47 are not limited to being shared by the display surfaces 51 and 52, and may be configured to be provided separately by the display surfaces 51 and 52, respectively.

  In the above-described embodiment, the case of the video camera 1 as the image sensor has been described. However, the present invention can also be applied to other imaging devices including a display unit, such as a digital still camera.

It is a perspective view showing the imaging | photography condition of the to-be-photographed object by the imaging device which concerns on the 1st Embodiment of this invention. It is a perspective view for demonstrating facing imaging | photography mode and normal imaging | photography mode. It is sectional drawing showing the structure of the display part shown in FIG. It is sectional drawing showing the structure of the organic electroluminescent panel and heat dissipation mechanism which were shown in FIG. It is a top view for demonstrating arrangement | positioning of the heat radiator in the organic electroluminescent panel shown in FIG. It is sectional drawing showing the structure of the organic electroluminescent panel at the time of a single-sided display state, and a thermal radiation mechanism. It is a schematic diagram for demonstrating the drive method of the heat radiator by microcomputer control. It is a flowchart showing the whole structure of a mode determination process. It is a flowchart showing the imaging | photography mode determination process shown in FIG. FIG. 9 is a flowchart showing a reproduction mode determination process shown in FIG. 8. It is a perspective view for demonstrating the display state at the time of reproduction | regeneration mode. It is sectional drawing showing the structure of the organic electroluminescent panel and heat dissipation mechanism which concern on the 2nd Embodiment of this invention. It is sectional drawing showing the structure of the organic electroluminescent panel at the time of a single-sided display state in FIG. 12, and a thermal radiation mechanism. It is a top view for demonstrating arrangement | positioning of the heat radiator which concerns on a modification. It is sectional drawing showing the structure of the organic electroluminescent panel and heat dissipation mechanism which concern on a modification.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Video camera, 2 ... Main body, 21 ... Operation part, 22 ... Microcomputer, 221 ... Control signal, 3 ... Lens part, 4 ... Display part, 51, 52 ... Display surface, 6 ... Viewfinder, 7 ... Battery pack, 8 ... Subject, 40 ... Organic EL element, 41 ... Organic EL panel, 42, 42A, 42B, 49 ... Heat radiator, 43 ... Heat conductive sheet, 44A, 44B ... Heat diffuser, 45, 45A, 45B ... Light reflecting layer , 46 ... surface protective sheet, 47 ... pixel, 48 ... switching unit, 401 ... glass substrate, 402 ... gate electrode, 403 ... gate insulating layer, 404 ... p-Si layer, 405 ... insulating layer, 406 ... wiring, 407 ... Source (drain) electrode, 408... Flattened layer, 409. Contact part, 410... Anode electrode, 411... Light emitting layer, 412. Seals, X ... object viewing direction, Y ... display unit opening and closing direction, P1, P2 ... object image, L1 ... top emission light, L2 ... bottom emission light, D ... display area, S ... switching element.

Claims (16)

A display panel including a plurality of light emitting elements having first and second display surfaces facing each other and constituting each pixel;
And a heat dissipator that is disposed in a region corresponding to between the pixels on at least one surface side of the first and second display surfaces, and that releases heat generated from the light emitting element. Display device. Each of the plurality of light emitting elements emits light to both sides of the first and second display surfaces.
The display device according to claim 1, wherein pixels constituting the first and second display surfaces are shared by the first and second display surfaces. Switching means for switching between a single-sided display state in which the emitted light is emitted only to the first display surface and a double-sided display state in which the emitted light is emitted to the first and second display surfaces;
The display device according to claim 2, wherein the heat radiating body is disposed at least on the second display surface side. The radiator on the second display surface side is movable in the in-plane direction of the second display surface,
The switching means drives the heat sink on the second display surface side to move to a region corresponding to the pixel on the second display surface side in the single-side display state, thereby The display device according to claim 3, wherein the two-sided display state is switched. A light reflecting layer having a light reflecting function is further provided on the surface on the display panel side of the radiator on the second display surface side,
In the single-sided display state, the switching means reflects the emitted light to the second display surface side and guides the second light to the first display surface side. The display device according to claim 4, wherein the heat radiating body on the display surface side and the light reflecting layer are driven. The radiator on the second display surface side further has a light reflecting function,
In the single-side display state, the switching means reflects the emitted light to the second display surface side and guides the emitted light to the second display surface side to the first display surface side. The display device according to claim 4, further comprising: driving a radiator on the second display surface side. The radiator on the second display surface side is provided in a plurality of stages in a direction orthogonal to the second display surface,
The display device according to claim 4, wherein the switching unit drives each of the plurality of heat radiators independently. The display device according to claim 3, further comprising a control unit that controls an operation of the switching unit. The display device according to claim 2, further comprising a heat dissipator that is thermally connected to the heat dissipator and dissipates heat released by the heat dissipator to the outside in the vicinity of the display panel. . The display device according to claim 2, wherein the heat radiating body is disposed on the first and second display surface sides. The display device according to claim 2, wherein the light emitting element is an organic EL element. Each pixel is arranged in a matrix in the display panel,
The display device according to claim 11, wherein the heat dissipating body is arranged in a lattice shape corresponding to the arrangement of each pixel. Each pixel is arranged in a matrix in the display panel,
The display device according to claim 11, wherein the heat radiator is disposed along only one of a horizontal line direction and a vertical line direction of the display panel. Each pixel is arranged in a matrix in the display panel,
The display according to claim 11, wherein the heat dissipating member is disposed only in a direction in which a region corresponding to the pixels is wider in a horizontal line direction and a vertical line direction of the display panel. apparatus. The display panel is
A transparent substrate constituting the second display surface;
Switching elements and wirings formed in regions corresponding to the pixels on the transparent substrate;
A plurality of the organic EL elements to which the switching elements and wirings are connected;
A partition separating each organic EL element;
A light-transmitting protective layer that is formed on the plurality of organic EL elements and the partition and constitutes the first display surface;
The radiator is disposed in at least one of a region corresponding to the partition on the front surface side of the protective layer and a region corresponding to the switching element or the wiring on the back surface side of the transparent substrate. The display device according to claim 11. Imaging means for imaging a subject;
Display means for displaying a subject image picked up by the image pickup means,
The display means includes
A display panel including a plurality of light emitting elements having first and second display surfaces facing each other and constituting each pixel;
An imaging device comprising: a heat dissipating body that is disposed in a region corresponding to the space between at least one of the first and second display surfaces and that emits heat generated from the light emitting element. apparatus.

Images