JP2003208112A - Image display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image display device capable of instantly supplying information for confirming updated information and information which is to be viewed for a very short period among information to be displayed on a light-emitting display screen for browsing without displaying them on the light- emitting display screen every time. <P>SOLUTION: The image display device houses an electronic display medium obtained by stacking display layers in which images are recorded by irradiation whit light carrying the images and application of voltage between a pair of electrodes to display the images on the electronic display medium. The image display device is provided with: a connecting part for connecting the housed electronic display medium in such a state to be arranged at a position of receiving light from the light-emitting display screen of a light-emitting display device which emits light carrying the images; a frame provided with a window part for the observation of the images recorded in the housed electronic display medium from the outside; and a voltage applying means for applying voltage to the electronic display medium housed in the frame. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a PC (Perso).
nal Computer) and PDA (Persona)
l Digital Assistant) and other predetermined information displayed on an information terminal having a light-emitting display screen,
The present invention relates to an image display device for recording and displaying on an electronic display medium at a predetermined timing.

[0002]

2. Description of the Related Art Conventionally, a CRT (CathodeRay Tub) has been used as a display means for information terminals and home electric appliances.
e), LCD (Liquid Crystal Dis)
play), ELD (Electro-Lumines)
center Display), PDP (Plasma)
Display Panel), LED (LightE)
Mitting Diode panel, OELD (Or
ganic Electro-Luminescent
A light emitting display device such as a display is used. Although they have a fast response speed and can be displayed in real time, they consume a large amount of power due to light emission. For this reason, when no operation is performed for a certain period of time, a method is adopted in which the power consumption is reduced and the light emitter is protected by shifting to a "standby state" in which light emission is stopped. Is widely used in.

However, in the standby state, the display is stopped, and the operation speed of the arithmetic processing unit for controlling the equipment is slowed or stopped. Therefore, the standby state is returned to the operating state. It takes a long time, and even if it is only to confirm whether or not an e-mail has arrived, or even if the user wants to see information for an extremely short period of time, it may be uncomfortable for a certain period of time.

On the other hand, the optical writing type electronic display medium using the liquid crystal having a memory property has an advantage that the power for displaying the written image is unnecessary and the power required for writing is very small. Since it takes 0.1 to 1 second to rewrite, the pointer display by the mouse, pull-down menu display, window movement / enlargement / reduction GUI (Graphical User), etc.
It is not suitable for displaying images that change instantaneously, such as interface display and moving image display.

[0005]

SUMMARY OF THE INVENTION In view of the above circumstances, the present invention is sufficient for checking the updated information among the information displayed on the light emitting display screen of the light emitting display device and for viewing for a very short time. An object of the present invention is to provide an image display device that can be immediately viewed without displaying information on the light emitting display screen each time.

[0006]

In order to achieve the above object, the present invention is a display layer in which an image is recorded between a pair of electrodes by irradiating light carrying an image and applying a voltage between the electrodes. In an image display device for accommodating an electronic display medium formed by stacking and displaying an image on the electronic display medium, the electronic display medium is accommodated, and the accommodated electronic display medium emits light carrying an image. A frame provided with a coupling unit that is coupled to a state of receiving light from the light emitting display screen of the light emitting display device, and a window unit for externally observing an image recorded on the accommodated electronic display medium. And a voltage applying means for applying a voltage to the electronic display medium housed in the frame.

Here, a fixing member fixed to the light emitting display device is provided, and the coupling portion is in a closed state in which the frame is covered with an electronic display medium which covers the front surface of the light emitting display screen. It is preferable that the fixed member is moved relative to the fixed member between the open state retracted from the front surface of the light emitting display screen.

Further, it is preferable that the frame detachably accommodates the electronic display medium.

Further, the frame or the fixing member is provided with an image forming optical system for forming an image carried by the light emitted from the light emitting display device on an electronic display medium contained in the frame. Is preferred.

Further, the voltage applying means may have a detecting means for detecting the closed state, and apply a voltage to the electronic display medium when the closed state is detected by the detecting means. This is the preferred embodiment.

Further, the voltage applying means has an interface for transmitting and receiving a signal to and from the light emitting display device, and transmits a signal for stopping the light emission of the light emitting display screen after applying a voltage to the electronic display medium. It is also preferable that

An interface for transmitting / receiving a signal to / from the light emitting display device is provided, and a signal for changing the light emitting state of the light emitting display screen is transmitted in response to the relative movement of the frame to the closed state. It is also a preferable embodiment that a control means for applying a voltage from the voltage applying means to the electronic display medium is provided.

Further, the control means receives the update notification signal of the predetermined information displayed on the light emitting display screen from the light emitting type display device or the predetermined notification while the light emission of the light emitting display screen is stopped. When the time elapses, the signal for requesting the display of the information on the light emitting display screen is transmitted, and at the timing when the information is displayed on the light emitting display screen, the voltage applying means causes the electronic display medium to be displayed. It is preferable to apply a voltage to.

It is also preferable that the control means transmits a signal for stopping the light emission of the light emitting display screen after applying a voltage from the voltage applying means to the electronic display medium.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the image display device of the present invention will be described below.

FIG. 1 is a schematic perspective view showing the image display device of the first embodiment.

As shown in FIG. 1, the image display apparatus according to the present embodiment has a frame 1 for accommodating an electronic display medium 4 having a display layer on which an image is recorded laminated, and an electronic device accommodated in the frame 1. A power supply circuit (not shown here) for applying a voltage for recording an image on the display medium 4 is provided. The frame 1 has a window portion 3 for allowing an image recorded on the contained electronic display medium 4 to be observed from the outside.
The electronic display medium 4 accommodated in the personal computer (hereinafter,
It is abbreviated as "PC". ) Or a convex portion 7 forming a part of a coupling portion 9 that is coupled to the light emitting display portion 6 of a light emitting display device such as a mobile terminal having a light emitting display screen. ing.

The image display device of this embodiment is further provided with a cover 2 as a fixing member which is fixed to the light emitting display device, and grooves on the both outer side surfaces of the cover 2 which form a part of the joint portion 9. 8 is dug, and the frame 1 is covered with the cover 2 by fitting the protrusions 7 provided in the frame 1 in which the electronic display medium 4 is housed into the grooves 8 of the cover 2.
Can be moved relative to.

Here, "relative movement" means that the electronic display medium 4 housed in the frame 1 is in a closed state in which the front surface of the light emitting display unit 6 is covered, and the electronic display medium 4 housed in the frame 1 emits light. This means that the frame 1 moves with respect to the cover 2 between the open state in which the part 6 is retracted from the front surface.

The connecting portion 9 in this embodiment can move the frame 1 relative to the cover 2 by sliding the convex portion 7 of the frame 1 and the groove 8 of the cover 2 in the arrow Y direction.

Here, the joint portion 9 is formed by fitting the groove 8 and the convex portion 7, but the joint portion 9 is not limited to this, and is formed by, for example, a hinge, a rail, a pawl or the like. May cover frame 1 2
On the other hand, the relative movement may be performed by opening and closing or the relative movement may be performed by attaching and detaching.

In the electronic display medium 4, a liquid crystal layer and a photoconductive layer are laminated, and light carrying an image is irradiated from the back surface side on which the photoconductive layer is laminated, and recording is performed from the front surface side on which the liquid crystal layer is laminated. A type that reads an image is used. As a result, the image displayed on the light emitting display unit 6 is recorded on the electronic display medium 4 in the closed state in which the frame 1 is closed, and the recorded image is output from the window portion of the frame regardless of the closed state or the open state. Can be observed.

In order to record and display the image (A) displayed on the light emitting display section 6 of the light emitting display device on the electronic display medium 4, the electronic display medium is accommodated in the frame 1 and the connecting portion of the frame 1 is used. The electronic display medium 4 is slid in the direction of the arrow Y to close the front surface of the light emitting display unit 6, and a voltage is applied from a power supply circuit (not shown here). In the display layer of the electronic display medium 4, the light emitting display section 6 is provided.
A reflection type image (A) that reflects light corresponding to the image (A) displayed on the screen is recorded, and after the application of the voltage is stopped, the coupling portion 9 is also slid to display the light emitting display portion 6. Since the reflected image (A) is maintained as it is even after the electronic display medium 4 is retracted from the front side and brought into the open state, the image recorded on the electronic display medium 4 is observed through the window portion 3 of the frame. be able to.

In this figure, the light emitting display section 6 is in an open state so that it can be directly observed. In this case, the observer arranges the electronic display medium 4 and the light emitting display section 6 of the light emitting display device 6 side by side. The displayed images (here, the same image is shown, but different images can be displayed) can be viewed at the same time, and the display area can be doubled and used.

FIG. 2 is a schematic sectional view showing an example of the electronic display medium used in this embodiment.

In the electronic display medium of this embodiment, a display layer on which an image is recorded by irradiating light carrying an image and applying a voltage between the electrodes is laminated between a pair of electrodes. The image recorded on the display layer can be rewritten any number of times, and the recorded image is maintained as it is after the voltage is removed. For the display layer, an electronic display medium using a memory type liquid crystal such as cholesteric liquid crystal, smectic liquid crystal, bistable nematic liquid crystal or a memory type display material such as electrophoresis is suitable.

The electronic display medium shown in FIG. 2 has a transparent substrate 1.
Between the electrode 12a formed on 1a and the electrode 12b formed on the transparent substrate 11b, the liquid crystal layer 13 made of cholesteric liquid crystal having a memory property and the resistance value changes when the writing light is irradiated. The photoconductive layer 15 is laminated, and the photoconductive layer 15 is further composed of charge generating layers 15a and 15c and a charge transporting layer 15b.

The liquid crystal layer 13 and the photoconductive layer 15 can both be electrically represented by a parallel circuit of a resistor and a capacitor, and the electronic display medium has the parallel circuit further connected in series. Therefore, when a voltage is applied between the electrodes 1a and 1b from the power supply circuit 10 while irradiating the photoconductive layer 15 with light, the liquid crystal layer 13 has an amount corresponding to the intensity distribution of the irradiated light. Because pressure is applied,
The liquid crystal layer 13 has an orientation distribution according to the intensity distribution of the irradiated light, and a reflection type image is recorded.

In this case, when the reading light is incident on the photoconductive layer 5 through the liquid crystal layer 13, the intensity distribution of the light irradiated on the liquid crystal layer 13 varies, and writing cannot be performed well.
When reading the written image, if the light transmitted through the liquid crystal layer 13 from the photoconductive layer 5 side reaches the eyes of the observer, the contrast of the displayed image is lowered and the visibility of the recorded image is deteriorated. By providing the light shielding layer 14 between the liquid crystal layer 13 and the photoconductive layer 15, they can be prevented.

The electronic display medium is sandwiched between the substrates 11a and 11b as a base material of the electronic display medium and in order to secure the mechanical strength of the electronic display medium.

The following materials are used for the electronic display medium.

The electrodes 12a and 12b are made of a metal thin film such as Au or ITO (Indium Tin Oxid).
e), an oxide such as SnO ₂ , ZnO, a thin film of a conductive polymer such as polypyrrole, or the like, and a light-transmitting electric conductor is used.

As the liquid crystal layer 13, nematic liquid crystals, chiral nematic liquid crystals, smectic A liquid crystals, chiral smectic liquid crystals, discotic liquid crystals, etc. can be used, and chiral nematic liquid crystals, surface-stabilized chiral smectic C liquid crystals, bistable twisted nematic liquid crystals, fine particles. A memory-type liquid crystal such as a dispersed liquid crystal is used. The display mode is ECB (Electrically Contro)
Known display modes such as an illuminated birefringence mode, a selective reflection mode, a Guest-Host mode, and a scattering-transmission mode can be used. In addition, in order to assist the optical change of the liquid crystal, passive optical components such as a polarizing plate, a retardation plate, a color filter, and a reflection plate are used together,
A dichroic dye may be added to the liquid crystal. The thickness of the liquid crystal layer 13 is usually in the range of 1 to 100 μm.

As liquid crystal materials, known liquid crystal compositions such as cyanobiphenyl, phenylcyclohexyl, phenylbenzoate, cyclohexylbenzoate, azomethine, azobenzene, pyrimidine, dioxane, cyclohexylcyclohexane, stilbene, and tolan are used. Is available. A dye such as a dichroic dye and an additive such as fine particles may be added to the liquid crystal material, and the liquid crystal material may be dispersed in a polymer matrix, polymer gelled, or microencapsulated. . Further, the liquid crystal may be any of a polymer, a medium molecule, a low molecule, and a mixture thereof.

As the photoconductive layer 15, (a) the inorganic semiconductor material is; amorphous silicon, ZnSe, CdS.
Compound semiconductors such as, (b) organic semiconductor materials; a complex of (c) a charge generating material that generates a charge by light irradiation and a charge transporting material that causes a charge transfer by an electric field, such as anthracene and polyvinylcarbazole; Generating materials such as perylene-based, phthalocyanine-based, bisazo-based, dithiopitokelopyrrole-based, squarylium-based, azulenium-based, thiapyrylium-polycarbonate-based compounds, and the like, and charge-transporting materials such as trinitrofluorene-based and polyvinylcarbazole System, oxadiazole system, pyrarizone system, hydrazone system, stilbene system, triphenylamine system, triphenylmethane system,
A diamine-based compound, an ion conductive material such as a polyvinylinole alcohol or a polyethylene oxide added with LiClO ₄ , or the like is used. As the composite form of the composite, a laminate, a mixture, a microcapsule, or the like can be used. The film thickness of the photoconductive layer 15 is preferably in the range of 1 to 100 μm, and it is desirable that the resistance ratio between light irradiation and non-irradiation is large.

As the light shielding layer 14, a material having a low light transmittance and a high electric resistance is used.

A transparent dielectric is used for the substrates 11a and 11b. For example, glass, ceramics, resins such as polyethylene terephthalate, polycarbonate, polyether sulfone, and polyolefin can be used.

Next, a second embodiment of the present invention will be described.

The second embodiment is different from the first embodiment in that the image forming optical system for forming the image displayed on the light emitting display screen of the light emitting display device on the electronic display medium and the frame are closed. The difference is that the detection means for detecting the movement to is provided. Therefore, the difference will be described.

FIGS. 3 and 4 are schematic side views of the image display apparatus according to the second embodiment. FIG. 3 shows the frame in an open state with respect to the cover, and FIG. 4 shows the frame in a closed state with respect to the cover. Is shown.

The image display device shown in FIGS. 3 and 4 includes a frame 1 for accommodating an electronic display medium 4 and a power supply circuit 1 for applying a voltage to the electronic display medium 4 accommodated in the frame.
0 and a light-emitting display device 28 that emits light carrying an image
And a cover 2 as a fixing member fixed to the frame 1. The frame 1 is provided with the accommodated electronic display medium 4 at a position for receiving light from the light emitting display unit 6 of the light emitting display device 28. A coupling unit 9 for coupling the states and a window unit 7 for externally observing an image recorded on the accommodated electronic display medium 4 are provided.

The frame 1 is provided with an insertion opening 1a,
The electronic display medium 4 can be detachably accommodated in the frame 1 by inserting and removing it from the insertion opening 1a.

Here, the electronic display medium 4 does not necessarily need to be detachably accommodated in the frame 1, and may be fixedly accommodated, but if it is detachably accommodated, the electronic display medium 4 having different characteristics is intended. The electronic display medium 4 on which the image is written can be used as a printer instead of being replaced with another printer.

The coupling section 9 is arranged between the electronic display medium 4 housed in the frame 1 in a closed state in which the electronic display medium 4 covers the front surface of the light emitting display section 6 and in an open state in which the electronic display medium 4 is retracted from the front surface of the light emitting display section 6. It is configured so that it can be moved relative to the cover 2 in the arrow Y direction. A closed state detection unit 10a connected to the power supply unit 21 of the light emitting display device is provided on the back surface of the coupling unit 9, and when the coupling unit 9 relatively moves to the closed state, the closed state detection unit 10a The power supply circuit 10 is supplied with power from the power supply circuit 10 by coming into contact with the closed state detection contact piece 10c protruding from the power supply circuit 10. Further, an electrode contact 10b is connected to the power supply circuit 10, and when the electronic display medium 4 is accommodated in the frame 1, the electrode contact 10b and a pair of electrodes of the electronic display medium 4 come into contact with each other. When is closed, a predetermined write voltage is automatically applied to the electronic display medium 4.

Here, the power source unit 2 connected to the commercial power source
1 is provided in the light emitting display device 28 housed in the cover 2, but the power supply unit 21 does not necessarily include the light emitting display device 2.
8 does not need to be provided and can be accommodated in the frame.

Emissive display device 28 to which the cover 2 is fixed
As CRT, LCD, ELD, OELD, PD
A light emitting display device 28 having a known light emitting display unit 6 such as a P or LED panel is used. Among them, the liquid crystal itself of the LCD is a non-luminous material, so that a light emitting display screen is formed by using it together with a backlight or a front light. The arithmetic processing unit 20 of the light emitting display device 28 is housed in the cover 2, and the image displayed on the light emitting display unit 6 changes according to the processing result. In addition, the cover 2 accommodates the arithmetic processing unit 20 and the power supply unit 21 that supplies electric power to the light emitting display unit 6, and when the light emitting display unit 6 is put in the standby state, the arithmetic processing unit 20 is operated from the power supply unit 21. The power supply to the light emitting display unit 6 is stopped, the processing speed of the light emitting display device 28 is reduced, or the processing operation is stopped.

Here, the arithmetic processing unit 20 and the power supply unit 21 do not necessarily have to be housed in the cover 2, but can be housed in the frame 1. The arithmetic processing unit 20 includes at least a CPU, a memory, and an interface circuit, and the light-emitting display device 28 includes an input device such as a keyboard, a touch panel, a mouse, a touch pad, a point stick, an auxiliary storage device, a communication device, and the like. It may be included, and may further function as a PC or PDA.

The power supply circuit 10 housed in the frame is equipped with a relay (not shown). When the frame 1 is closed with respect to the cover, the detection unit 10a contacts the closed state detection contact piece 10c protruding from the power supply circuit 10. Then, when the closed state is detected, the relay operates. An interface (not shown), for example, a pin connector, is formed between the image display device and the arithmetic processing unit 20 of the light emitting display device 28. When the relay of the power supply circuit 10 operates, the light emitting display unit 6 stops emitting light. The power supply circuit 10 transmits a stop signal to cause the stop. When the arithmetic processing unit 20 of the light emitting display device 28 receives the stop signal from the power supply circuit 10 via the interface, the arithmetic processing unit 20 switches the power supply unit 21 from the commercial power source or the light emitting display unit 6 to the switch. The switch for cutting off the power supply is operated to stop the light emission of the light emitting display unit 6.

The frame 1 of this embodiment further includes an image forming optical unit 5 for forming an image emitted from the light emitting display device 28 on the electronic display medium 4 housed in the frame 1. Since the light emitted from the light emitting display unit 6 is collected when the light emitting device 1 is in the closed state and the image carried by the light is focused on the display layer of the electronic display medium, the light emitting display unit 6
Even if there is a slight gap between the electronic display medium and the electronic display medium, when the writing voltage is applied from the power supply circuit 10 while the light emitting display unit 6 is emitting light, the image carried by the light is clearly displayed on the electronic display medium 4. Written.

Although the imaging optical unit 5 is arranged on the frame 1 side here, it may be arranged on the cover 2 side. Further, by providing the image forming optical unit 5, the electronic display medium 4
Although a clear image can be recorded, it is not always necessary to provide the imaging optical unit 5 depending on the brightness and definition of the light emitting display unit 6 of the light emitting display device 28.

As described above, when the frame 1 is closed, the image display last displayed on the light emitting display device 28 is recorded on the electronic display medium 4, so that the light emitting display devices 28 are individually displayed. The displayed contents can be browsed without starting. In addition, in the electronic display medium 4, for example,
You can record contact addresses and phone numbers that you need to see frequently, schedules, memos, maps, etc. and use them as a notebook, or you can display your favorite photos etc. and use them as so-called standby images. . Figure 5
It is a figure which shows an example of an imaging optical part, FIG.5 (a) is a schematic diagram which shows a three-layer laminated lens array, and FIG.5 (b) is
It is a schematic diagram which shows a Selfoc (registered trademark) lens array.

The light emitted from the light emitting display section 6 has a diffusing property so that the light emitting display device 28 can be visually recognized in a wide viewing angle. Further, a glass substrate, a polarizing plate, a retardation plate, an antireflection film, an electromagnetic wave prevention plate, a touch panel, etc. are interposed between the surface of the light emitting display unit 6 of the light emitting display device 28 and the light emitting portion. It is common. Therefore, in order to write an image on the electronic display medium 4, even if the electronic display medium 4 is placed in close contact with the light emitting display unit 6 of the light emitting display device 28, a space of about 0.5 to 2 mm is provided, and the electronic display medium 4 is Even if an image is recorded on the image, the image is blurred, and there is a limitation in increasing the resolution of the written image. Therefore, the light emitting display unit 6 of the light emitting display device 28
When writing the image displayed on the electronic display medium 4, it is preferable to arrange the surface of the light emitting display unit 6 and the light emitting portion as close as possible. Therefore, an imaging optical system is provided between the light emitting display unit 6 and the electronic display medium 4,
It is preferable to form an image displayed on the light emitting display unit 6 on the electronic display medium 4. The imaging optical system includes (1) an erecting imaging optical system arranged in an array; for example, a SELFOC lens array in which rod-shaped lenses of a gradient index type are integrated in an array, or a microlens array having two layers. Or one that is laminated in three layers to form an upright image,
(2) A cylindrical light absorber array or the like that absorbs diffused light and turns it into parallel rays is used.

The three-layer laminated lens array shown in FIG. 5A has a structure in which a lens array 31 having microlenses 30 arranged in a two-dimensional plane is laminated in three layers. Has a light emitting display screen
An electronic display medium for forming an image emitted from the light emitting display screen is arranged above the layered lens array.

Microlenses 30 are arranged on the entire surface of the two-dimensional plane of the lens array 31 at an optimum pitch, and the illuminance distribution on the electronic display medium is substantially uniform. Each of the microlenses 30 arranged in the lens array 31 may have a structure in which a member forming a plane is perforated and fitted therein, or a plurality of microlenses formed on the surface of a plastic plate forming the plane. But it's okay.

An optical path 32 of an image forming optical system unit 33 which is one unit of a three-layer laminated lens array is shown in the figure, and three microlenses 30 are arranged in the optical path 32 shown in the figure. Since the images emitted from the light emitting display screen are accurately reproduced by smoothly connecting the images formed by the respective image forming optical system units 33 of the three-layer laminated lens array, an erecting equal-magnification image is formed on the electronic display medium. It

The optical path 3 of each imaging optical system unit 33 is provided between the lens arrays 31 of the three-layer laminated lens array.
Spaces other than 2 are preferably shielded to prevent stray light, and spacers that keep the distance between the lens arrays 31 constant are preferably sandwiched.

In the SELFOC lens array shown in FIG. 5B, the SELFOC lens 38 in which the refractive index of the cross section 39 is distributed, for example, in a parabolic shape between the pair of substrates 37.
However, a plurality of optical paths 32 are arranged in parallel, and the light incident from one cross section of the SELFOC lens 38 is 1 from the other cross section.
It is configured to emit 100%.

Next, a third embodiment of the present invention will be described.

The third embodiment is different from the second embodiment in that the coupling portion between the frame and the cover is constituted by a hinge, and the light emitting display portion of the light emitting display device emits light when the frame is closed. When the predetermined information is updated or when the predetermined time has elapsed while stopped, the information is displayed on the screen each time, and a writing voltage is applied to the electronic display medium to display the information on the screen. The difference is that a control unit for recording information and displaying the screen and stopping the voltage application is provided, but the other points are common, and the difference will be described.

6 and 7 are schematic side views of the image display apparatus according to the third embodiment. FIG. 6 shows the frame in an open state with respect to the cover, and FIG. 7 shows the frame in a closed state with respect to the cover. Is shown.

The image display device of the present embodiment is different from the image display device of the second embodiment in that the coupling part is constituted by a hinge, the image display of the light emitting display part is stopped, and the frame is closed. In, while the predetermined information is automatically displayed on the light-emitting display unit of the light-emitting display device on a regular basis, and a control unit for recording the information on the electronic display medium is provided, except that it is common, The same components are designated by the same reference numerals, and duplicate description will be omitted.

In FIGS. 6 and 7, the image display device includes a frame 1 for accommodating the electronic display medium 4, a cover 2 fixed to the emissive display device 28 by accommodating the emissive display device 28, and a frame. It is provided with a connecting portion 9 formed of a hinge for connecting 1 and the cover 2. The coupling unit 9 opens and closes the frame with respect to the cover by using the hinge as a fulcrum so that the electronic display medium 4 accommodated in the frame 1 covers the front surface of the light emitting display unit 6, The electronic display medium 4 housed in 1 can be moved relative to the open state retracted from the front surface of the light emitting display section 6, and when the electronic display medium 4 is closed, the electronic display medium can be moved from the light emitting display section 6 to the optical state. It can be placed in a position to receive.

When an image is displayed on the light emitting display unit 6 of the light emitting display device 28 and a predetermined process is performed using an input means such as a touch panel, the frame 1 is opened and the predetermined process is performed. And after the predetermined processing is completed,
The power supply unit 21 is cut off or the save mode is set to stop the image display of the light emitting display unit 6, and the frame 1 is closed.

When the light emitting display unit 6 is started to emit light and the frame 1 is closed, when the light emitting display unit 28 is activated, the light emitting display unit 28 receives, for example, a mail or updates the display information. When such information is displayed, the information is displayed on the light emitting display unit 6 and a writing voltage is applied to the electronic display medium to record the information displayed on the screen on the electronic display medium. There is provided a control unit 35 for performing control for stopping both the and, and the control unit 35 and the arithmetic processing unit 2 of the light emitting display device 28.
An interface 36 formed of, for example, a pin connector or the like for transmitting and receiving signals to and from each other is formed between 0 and 0. The light-emitting display device 28 sends an update notification signal when it receives web page update information including the latest stock quotes and news, or when a new mail is received, for example. The control unit 35 activated by operating the operator does not receive the update notification signal via the interface 36, determines whether the update notification signal is the preset information update notification signal, and applies it. In this case, a display request signal for displaying the information on the light emitting display unit 6 is transmitted.

Further, even if the light-emitting display device 28 does not transmit the update notification signal, the control unit 35 has a timer function, so that the information set in advance at the preset time interval is displayed in the light-emitting display unit. A display request signal to be displayed on 6 can also be transmitted.

This display request signal is sent to the interface 36.
Is received by the arithmetic processing unit 20 via the
Performs predetermined processing and causes the light emitting display unit 6 to emit light to display the requested information as an image. The control unit 35
At the timing when the image is displayed on the light emitting display unit 6, the electronic display medium 4 is supplied from the power supply circuit 10 via the electrode contacts 10b.
A writing voltage is applied to the electronic display medium 4 to record the image displayed on the light emitting display unit 6. Then, the control unit 35 disconnects the voltage applied from the power supply circuit 10 at the timing when the image is recorded on the electronic display medium 4.

Further, the electronic display medium 4 on which the image is recorded
Is contained in frame 1, but frame 1
Since the window portion 3 is provided for observing the image recorded on the electronic display medium 4 from the outside, the power source portion 21 of the light emitting display device 28 is cut off, or the save mode is set to display the image on the light emitting display portion 6. Even when the power is stopped, without turning on the power one by one with the frame 1 closed,
The regularly updated images of preset information can be seen immediately.

FIG. 8 is a diagram showing a control flow by the control unit.

In FIG. 8, when the operator of the control unit is operated to select information to be displayed periodically (S-
1), the control unit determines whether the frame is in the closed state (S-2).

Here, the closed state of the frame may be determined by providing a sensor or a contact on the frame or the cover or by providing a contact on the coupling portion 9, or by the operator who operates the button. You can also leave it to.

When the frame is in the closed state, the selected display information is selected as the information for transmitting the update notification signal or the information for not transmitting the update notification signal, for example, the information for not transmitting the update notification signal. In this case, the timer function is set and a display request signal for displaying the selected information on the light emitting display device is transmitted (S-3), and the arithmetic processing unit of the light emitting display device causes the display request signal to be displayed. Is received, and the requested information is displayed as an image on the light emitting display unit.

The control unit transmits the display request signal and then
A writing voltage is applied between the pair of electrodes of the electronic display medium from the power supply circuit for a predetermined time at a predetermined timing when an image is displayed on the light emitting display unit (S-4).

Image-bearing light emitted from the light-emitting display section is irradiated, and the electronic display medium to which a voltage is applied has an orientation distribution corresponding to the intensity distribution of the image-bearing light and is reflected. The mold image is recorded.

After a predetermined voltage is applied from the power supply circuit to record an image on the electronic display medium, the control section issues a stop signal for stopping the light emission of the light emitting display section (S-5), and the light emitting type display is displayed. The arithmetic processing unit of the device receives the stop signal,
The light emission of the light emitting display unit is stopped by turning off the switch of the power supply unit or the power supply switch to the light emitting display unit.

Since writing of an image takes a short time of 0.1 to 1 second, power consumption can be reduced by turning off the light emission from the light emitting display section of the light emitting display device 6 except when rewriting. . At this time, the power consumption can be further reduced by shifting the light emitting display device to the standby state.

After transmitting the stop signal, the control unit shifts to a standby state in which the elapse of a predetermined time by the timer function is monitored (S-6).

When a predetermined time elapses during this standby state, a trigger pulse is input (S-7), so that the control unit returns from the standby state (S-8) and again from (S-2). The flow up to (S-7) is executed.

[0078]

According to the image display device of the present invention, it suffices to confirm the update of preset information among the information displayed on the light emitting display screen of the light emitting type display device or to see it for an extremely short time. The information can be automatically and regularly viewed immediately without being displayed on the light emitting display screen each time.

[Brief description of drawings]

FIG. 1 is a schematic perspective view showing an image display device according to a first embodiment.

FIG. 2 is a schematic cross-sectional view showing an example of an electronic display medium used in this embodiment.

FIG. 3 is a schematic side view of an image display device according to a second embodiment.

FIG. 4 is a schematic side view of an image display device according to a second embodiment.

FIG. 5 is a diagram illustrating an example of an image forming optical unit.

FIG. 6 is a schematic side view of an image display device according to a third embodiment.

FIG. 7 is a schematic side view of an image display device according to a third embodiment.

FIG. 8 is a diagram showing a control flow by a control unit.

[Explanation of symbols]

1 frame 1a insertion slot 2 cover 3 windows 4 Electronic display media 5 Imaging optics 6 Light emitting display 7 convex 8 groove 9 connection 10 power supply circuit 10a detector 10b electrode contact 10c Closed state detection contact piece 11a, 11b substrate 12a, 12b electrodes 13 Liquid crystal layer 14 Light-shielding layer 15 Photoconductive layer 15a, 15c Charge generation layer 15b Charge transport layer 20 arithmetic processing unit 21 power supply 28 Emissive display device 30 micro lens 31 lens array 32 optical paths 33 Imaging optical system unit 35 control unit 36 interfaces 37 pair of substrates 38 Selfoc lens 39 cross section

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) G09G 3/02 G09G 3/02 Z (72) Inventor Yasunori Saito 2274 Hongo, Ebina-shi, Kanagawa Fuji Xerox stock Company Ebina Business Site (72) Inventor Tsunemasa Mita 2274 Hongo, Ebina City, Kanagawa Prefecture Fuji Xerox Co., Ltd. Ebina Business Site F Term (reference) 2H089 HA21 HA40 QA16 RA13 TA02 TA10 TA19 2H092 LA12 NA26 PA05 QA13 2H093 NA76 ND39 NE03 NE06 NE06 NE05 NE06 NE10 NF17 5C080 AA06 AA10 AA13 CC02 DD01 DD21 JJ01 JJ06 JJ07 5C094 AA22 BA01 BA21 BA44 BA47 BA48 BA49 BA75 CA19 DA02 DA08 HA08 HA10

Claims (9)

[Claims] 1. An electronic display medium containing a display layer, on which an image is recorded by irradiation of light carrying an image and application of a voltage between the electrodes, is housed between a pair of electrodes, and the electronic display medium is housed in the electronic display medium. In an image display device for displaying an image on a display medium, a position for receiving the light from a light emitting display screen of a light emitting display device that stores the electronic display medium, and stores the stored electronic display medium. And a frame provided with a coupling part for coupling to a state of being arranged in, and a window part for providing an image recorded on the accommodated electronic display medium for external observation, and a voltage is applied to the electronic display medium accommodated in the frame. An image display device comprising: a voltage application unit for applying the voltage. 2. A fixing member fixed to the light emitting display device, wherein the coupling portion is in a closed state in which an electronic display medium housed in the frame covers a front surface of the light emitting display screen. The image display device according to claim 1, wherein the image display device is moved relative to the fixed member between an open state retracted from the front surface of the light emitting display screen. 3. The image display device according to claim 1, wherein the frame removably accommodates the electronic display medium. 4. The frame or the fixing member includes an image forming optical system for forming an image carried by light emitted from the light emitting display device on an electronic display medium contained in the frame. The image display device according to claim 1 or 2. 5. The voltage applying means has a detecting means for detecting the closed state, and applies a voltage to the electronic display medium when the closed state is detected by the detecting means. The image display device according to claim 2, which is characterized in that. 6. The voltage applying means includes an interface for transmitting and receiving a signal to and from the light emitting display device, and transmits a signal for stopping the light emission of the light emitting display screen after applying a voltage to the electronic display medium. The image display device according to claim 5, wherein the image display device is a display device. 7. An interface for transmitting and receiving a signal to and from the light emitting display device is provided, and a signal for changing a light emitting state of the light emitting display screen is transmitted in response to the relative movement of the frame to a closed state. 3. The image display device according to claim 2, further comprising control means for applying a voltage from the voltage applying means to the electronic display medium. 8. The control means receives, when a light emission of the light emitting display screen is stopped, an update notification signal of predetermined information displayed on the light emitting display screen from the light emitting display device, or a predetermined signal. When the time elapses, the signal for requesting the display of the information on the light emitting display screen is transmitted, and at the timing when the information is displayed on the light emitting display screen, the voltage applying means causes the electronic display medium to be displayed. The image display device according to claim 7, wherein a voltage is applied to the image display device. 9. The control means transmits a signal for stopping the light emission of the light emitting display screen after applying a voltage from the voltage applying means to the electronic display medium. Item 7. The image display device according to item 7.