JPS6112166A - Picture display device - Google Patents

Abstract

PURPOSE:To attain the recording of picture information inputted additionally separately from other picture information by converting the inputted picture information only into an electric signal. CONSTITUTION:While a transparent film 27 for inputting additional picture and a belt-form photosensitive body 8 reproducing and displaying picture information converted already into an electric signal are observed externally from the direction of a display window hole 3, the picture is described on the transparent film 27. After the completion of addition, when the picture recorded on the film 27 reaches an exposure section 28, the picture is lighted and the image is formed on a CCD34, and converted into an electric signal. The picture on the film 27 is cleaned and removed by a cleaning member 38 and used for the next picture input.

Description

[Detailed Description of the Invention] [Technical Field] The present invention relates to an image display device that displays image information converted into an electrical signal as a visible microscopic image, and in particular, the present invention relates to an image display device that displays image information converted into an electrical signal as a visible microscopic image. The present invention relates to an image display device having means for converting an image into an electrical signal.

[Prior Art] Generally, CRT (cathode ray tube) type devices are widely used as image display devices for displaying data in computers, facsimiles, and the like.

In such a CRT type image display device, when adding a new image to the displayed image, the additional input is performed using a light bench, digitizer, etc., or using character keys, but the large capacity memory is required, making the configuration complex and expensive.

Further, when such an image addition input method is used, the types of image information that can be input are limited, and the resolution of the input image is relatively low.

On the other hand, as an alternative to such a CRT type image display device, the applicant has developed and proposed an image display device using an endlessly movable belt-like image carrier as shown in FIG. .

To explain the device shown in Fig. 1, 1 is a housing, 2 is a display part provided in the housing, 3 is a display window hole of the display part, and 4 is a rigid material such as an acrylic plate or glass attached to the display window hole. It is a transparent member. In addition, 5 is a scanner that scans laser light, and 6 is f
φθ lens, 7 is a reflecting mirror. Reference numeral 8 denotes an endless belt-shaped photoreceptor (hereinafter referred to as belt photoreceptor), and a guide roller is provided inside the housing 1! 1, 10, 11, and 12, and is installed as an image carrier that is intermittently driven by a driving means (not shown) connected to at least one of the guide roller shafts.

The output light of a semiconductor laser (not shown) modulated by the image electric signal is scanned in one direction by a scanner 5.
Further, the back surface of the belt-shaped photoreceptor 8 is exposed through the f-theta lens 6 and the mirror 7. The photoreceptor 8 is, for example, a transparent conductive substrate on which a photoconductive layer is provided.

A toner conveying magnet 18 rotates in the direction of the arrow in this figure, facing the surface of the belt-shaped photoreceptor 8 at the exposure position A.
A developing device 15 is provided with a sleeve 17 having a sleeve 17 on the inside, and a conductive and magnetic developer (toner) 18 supplied to the sleeve surface is uniformly regulated by a blade 19 and comes into contact with the photoreceptor surface. do. A DC voltage is applied between the sleeve of the developer and the base of the photoreceptor by a DC voltage source (see FIGS. 2 and 3). Further, rollers 13 and 14 are provided near the positions where exposure and development are performed, thereby keeping the belt-shaped photoreceptor 8 flat.
The distance between the surface of the photoreceptor and the sleeve of the developing device is kept constant with high precision. The toner image thus written and formed on the surface of the belt-shaped photoreceptor 8 by beam irradiation at the position A facing the developing device 15 is sent to the display section 2 .

This display section 2 is formed so that a rectangular window hole 3 is provided on the front surface of a housing 1, and a toner image on a photoreceptor can be viewed directly from the outside through a transparent member 4 that covers this window hole 3. When a predetermined visible image area coincides with the position of the window hole 3, the photoreceptor 8 can be stopped for an arbitrary period of time automatically or by operating a switch. And window hole 3
The toner image on the stationary surface of the photoreceptor can be visually observed through the transparent member 4.

Reference numeral 20 denotes a lamp for erasing the potential difference on the photoreceptor 8 caused by beam irradiation, and the lamp 20 is arranged opposite to the back surface of the photoreceptor 8 as described above.
It is disposed near the downstream side of the exposure position A, is turned on only while the belt-shaped photoreceptor 8 is moving, and is turned off when it stops. Reference numeral 21 denotes an operation section provided in the casing 1 below the display section 2, and has a plurality of operation buttons for instructing to stop the movement of the photoreceptor 8, etc.

FIGS. 2 and 3 are diagrams for explaining the principle of image formation on the belt-shaped photoreceptor 8 used in the apparatus shown in FIG.

FIG. 2 shows the state of charge in the bright part of the information light (laser light) LB. DC power supply E via sleeve 17
When the toner 18 to which a DC voltage of 1 is applied comes into contact with the photoreceptor 8, an electric field is also applied to the transparent conductive layer 8b of the photoreceptor 8.

At this time, information light passes through the transparent substrate (for example, polyethylene terephthalate film) 8a and is transmitted to the conductive layer 8b.
When irradiated with the photoconductive layer 8C, photocarriers e are generated in the photoconductive layer 8C, and the photocarriers are guided near the surface of the photoconductive layer 8C by the action of an electric field. As a result, a strong electrostatic attraction acts between the conductive and magnetic toner 18 and the photoconductive layer 8C, and the toner 18 is attached to the photoconductive layer 8C, that is, the surface of the photoreceptor 8.

In the illustrated example, the photoconductive layer 8c is an N-type semiconductor, and the toner 18
Since a positive voltage is applied to the information beam LB, negative carriers e generated near the substrate 8a in the photoconductive layer 8c by the irradiation with the information light LB are well guided toward the surface of the photoconductive layer 8C. The result is a plus toner! A strong electrostatic attraction force acts between the photoreceptor 8 and the photoreceptor 8, and the toner 18 adheres to the photoreceptor.

FIG. 3 shows the state of charge in the dark area. When an electric field is applied between the toner 18 and the transparent conductive layer 8b of the base, electrostatic attraction acts between the two, but there is a photoconductive layer 8C between them and they are separated by a distance. Therefore, its power is small. Therefore, the toner 18 is pulled away from the photoconductive layer 8C, that is, the surface of the photoreceptor 8, due to the magnetic force generated by the rotating magnet 18 provided inside the fixed sleeve 17 and the adhesion force between particles of the magnetic toner 18. .

Furthermore, when changing the toner image on the photoreceptor 8 mentioned above,
A new image can be formed simply by passing through the above exposure position A again. That is, when the toner holding portion of the photoreceptor 8 changes to a non-holding portion, the toner 18 whose electrostatic adsorption force has decreased is removed by the magnetic field of the magnet 18, resulting in a bright portion to which no toner is attached. On the other hand, if the toner is to be retained, the carrier e is injected again by the information light LB,
The toner 18 overcomes the magnetic field of the rotating magnet 16 and is taken out, continuing to hold the toner. Therefore, the toner image on the surface of the photoreceptor does not have any adverse effect on the image formation of the magnetic field.
There is no need to provide a separate cleaning means.

Note that while the endless belt-shaped image carrier is intermittently rotated,
Another method for displaying a predetermined formed image is Ag2Hg1. which is a compound of silver, mercury and iodine. For example, a heat-sensitive recording method may be used in which a heat-sensitive recording body having reversibility such as the above is formed as the above-mentioned beveled, and a heat-sensitive recording head is used as an image forming means.

In general, the image information signal input to the image display device as described above is information stored in an information storage medium such as an optical disk, which is stored and recorded as an electrical signal, or information stored in a storage circuit or the like. In order for the operator to additionally input new image information to image information that has already been converted into electrical signals, the image information that has already been converted into electrical signals is displayed as a visible image on an image display device for visual viewing. Afterwards, a processing step is required to input additional image information, convert the image information into electrical signals again, and transfer the information to an information storage medium or a storage circuit.

However, the conventional image display device shown in FIG. 1 does not have a means for converting the additionally input image into an electrical signal, so another method is required to carry out the process of additionally inputting the image. This has the disadvantage that an input device is required and the device configuration is complicated.

Furthermore, if image information that has been converted into an electrical signal is synthesized with newly added image information by some means and converted into an electrical signal, it becomes difficult to separate only the image information that was added after that. It had drawbacks.

[Objective] In view of the above points, the present invention enables image information that has already been converted into an electric signal and newly inputted image information to be observed on a display unit, and then displays the additionally inputted image. An object of the present invention is to provide an image display device that can convert information into electrical signals.

Another object of the present invention is to construct the above-mentioned device inexpensively and simply without using a large capacity memory.

Still another object of the present invention is to provide an image display device that is capable of recording or storing additionally inputted image information separately from other image information by converting it into an electrical signal. .

[Example] Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 4 shows an example of the internal configuration of an image display device to which the present invention is applied, and parts similar to those of the device in FIG. 1 are given the same reference numerals.

In FIG. 4, 23 to 26 are rollers, and 27 is an endless transparent film such as a polyester film. This transparent film 27 is a second image bearing member for inputting an additional image, and the transparent member 4 of the display window hole 3 is sandwiched between the four wooden rollers 23 to 4.
28, one of these rollers (e.g. 28)
is rotated and moved in the direction of arrow D in the figure.

In addition, since the transparent film 27 is disposed close to the front of the belt-shaped photoreceptor 8, which is the first image-bearing member that reproduces and displays image information converted into an electrical signal into a visible image, the belt-shaped photoreceptor 8 The image carried on the display window 8 can be observed from the outside through the transparent film 27 and the transparent member 4 from the direction of the display window hole 3. Further, since a part of the transparent film 27 is arranged in close contact with the front surface of the rigid transparent member 4, an image can be written by hand or ink on the transparent film 27 from the direction of the display window hole 3. This newly added image on the transparent film 27 can be observed by optically superimposing the image carried on the belt-shaped photoreceptor 8.

In this way, in this apparatus, the user observes the image carried on the belt-shaped photoreceptor 8 while moving the transparent film 2.
7, a new image can be added and visually recognized.

After this additional writing is completed, the drive roller 26 is driven to move the transparent film 27 in the direction of the arrow. The drive roller 28 is driven by operating the operation button 22 of the operation section 21.

When the image recorded on the transparent film 27 reaches the position of the exposure section 28 due to the movement of the film 27, the illumination lamp 2
The light emitted from 8 illuminates the image, and its reflected light image is reflected by reflection mirrors 30 and 31, and is imaged by an imaging lens 33 onto a charge-coupled device (hereinafter referred to as COD) 34. .

At this time, since the surface of the drive roller 26 is white and the image on the transparent film 27 is formed with colored ink, the CCD 34 uses the contrast between the ink color and the white surface of the drive roller 26 to print the image on the transparent film 27. The image information is read and converted into an analog electrical signal according to its contrast. Furthermore, since the transparent film 27 is moving while the image is being read by the CCD 34, all images on the transparent film 27 are scanned and read by the CCD 34 and converted into electrical signals.

After passing through the exposure section 28, the image written on the transparent film 27 with ink is cleaned and removed by a downstream cleaning member 38 fixed to the light shielding plate 37. That is,
The cleaning member 38 is made of a flexible member such as a sponge or felt impregnated with alcohol or the like, and is placed under pressure against the drive roller 26, so that the image on the transparent film 27 is not visible to the cleaning member 38. It can be wiped off with. In this way, all images on the transparent film 27 are removed and the transparent film 27 is prepared for the next image input.

FIG. 5 shows an example of the configuration of the signal processing system of the apparatus of the present invention shown in FIG. Here, 40 indicates the entire image display device, in addition to the CCD 34 and laser scanner 5 shown in FIG.
A binarization circuit 41 that converts the analog signal outputted from 34 into a binary digital signal, a laser drive circuit 42 that generates laser light, and an interface circuit 43 that transmits and receives signals between both circuits 41 and 42 and the outside. have Further, 44 is a common path line, 45 is a system controller that performs overall control, and 46 is an optical disk device that stores image information converted into electrical signals.These system controller 45, optical disk device 46, and interface The circuit 43 is connected to the above-mentioned common path line.

The above-mentioned system controller 45 is connected to the image display device 40
and the optical disk device 46, or control the operation of each device, and furthermore, the path line 4
4 and performs various arithmetic processing.

Further, the above-mentioned optical disk device 48 records information converted into an electrical signal onto an optical disk which is an information recording medium, and also reads information recorded on the optical disk as an electrical signal and outputs it to the pass line 44.

With the above configuration, the image information written on the transparent film 27 is converted into an analog signal by the CCD 34, and the CCD
The image information converted into an analog electrical signal by 34 is
The signal is converted into a digital signal by the digitization circuit 41, output from the interface circuit 43 to the pass line 44, sent to the optical disc device 48 via the system controller 45, and recorded on the optical disc by the optical disc device 4B.

Further, the image information recorded on the optical disk is read by the optical disk device 48, taken into the image display device 40 via the pass line 44, and input to the laser drive circuit 42 via the interface circuit 43. A visible image is formed on the belt-shaped photoreceptor 8 by the laser scanner 5.

Therefore, the image input onto the transparent film 27 is recorded on the optical disk of the optical disk device 46 separately from other image information, and the recorded information is read out from the optical disk as necessary and displayed on the image display device. 40 or input to the system controller 45 as image information. Note that in order to realize the above functions, there is no need to use large capacity memory in this example.
Therefore, it can be realized relatively inexpensively.

Further, in the above-described embodiment, the belt-shaped photoreceptor 8 was used as the first image-bearing member, but the present invention is also applicable to image-bearing members of other types of image display devices (for example, CRT displays, liquid crystal displays, etc.). It is also possible to use the member as a first image-bearing member.

Furthermore, in the above-described embodiment, the transparent film 27 is used as the second image-bearing member, and the images carried by both the first and second image-bearing members are superimposed so that they can be visually recognized. This configuration is not essential to the present invention, and it is sufficient as long as it is possible to read at least the image on the second image bearing member, so the second image bearing member is not particularly limited to a transparent film.

[Effect] As explained above, according to the present invention, it is possible to separate only additionally input image information from other image information and convert it into an electric signal for an image signal that has already been converted into an electric signal. I can do it.

Further, according to the present invention, the above-mentioned functions can be realized simply and inexpensively without using a large-capacity memory.

[Brief explanation of drawings]

FIG. 1 is a side sectional view showing an example of the internal configuration of a conventional image display device, and FIGS. 2 and 3 are explanatory diagrams showing the principle of image formation on the belt-shaped photoreceptor 8 used in the device shown in FIG. , FIG. 4 is a side sectional view showing an example of the internal configuration of an image display device to which the invention is applied, and FIG. It is a block diagram showing an example. 5... Laser scanner, 8... Belt-shaped photoreceptor as first image-bearing member, 15... Toner developer, 27... Transparent film as first image-bearing material, 28
...Exposure section, 29.. Illumination lamp, 30.31.. Mirror, 33.. Lens, 34.. Charge coupled device (COD). 41... Binarization circuit, 42... Laser drive circuit, 43... Interface circuit, 45... System controller. 46... Optical disk device. Figure 5 4h

Claims (1)

[Scope of Claims] A first image carrying member carrying a microscope image formed from image information converted into an electrical signal; a second image carrying member that carries image information as a visible image; and an image reading means that reads only the visible image carried by the second image carrying member and converts it into electrical signalized image information. An image display device characterized by: