JP2009216807A - Display system and driving device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display system and a driving device, the display device being a rewritable display device which is made to be a paper-like display by reducing the number of components. <P>SOLUTION: The frontplane part is disposed on the display device 100, the backplane part is disposed on the driving device 200, the display device 100 is set to be attachable and detachable and the display device 100 is loaded to the driving device 200 only when rewriting is performed. The display device 100 comprises a common electrode and a display element. The driving device 200 has: a first substrate 220 on which pixel electrodes are mounted; a driving circuit 231; a retention member 250 which fixedly retains the display device 100; and an energizing member 240 which energizes the display device 100 in the direction of the first substrate 220. When performing rewriting, the driving device 200 energizes the display device 100, conducts electricity to the common electrode, at the same time, supplies a voltage signal in accordance with an image to be written into the pixel electrodes and, thereby, a voltage is applied to the display element of the display device. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a display device using a so-called memory display element.

So-called electronic paper is generally a display device intended to be handled like paper, and is also called a paper-like display because of its characteristics (see, for example, Patent Document 1). “Like paper (paper-like)” in this case often means that rewriting can be repeated, and that it is lightweight and thin, and can be easily carried. In electronic paper, the use of memory-type display elements, that is, display elements that can maintain a display state even when no voltage is applied, can reduce power consumption and contribute to weight reduction and thickness reduction. To do.
JP 2005-192071 A

When there are many parts of electronic paper, it becomes easier to increase the weight and thickness, and the “paperiness” is impaired. In addition, the electronic paper has a more complicated configuration as it has more parts, and is more likely to fail due to dropping or bending. On the other hand, even if paper is dropped or bent, it usually has no problem in its use.
Therefore, an object of the present invention is to make a rewritable display device more paper-like by reducing the number of parts.

  The drive device according to the present invention is a display device that is detachable from its own device, the holding member holding the display device having a display surface and a common electrode corresponding to the display surface so as not to move, Common to the substrate having an electrode surface at a position corresponding to the display surface of the display device held by the holding member, the pixel electrode provided on the electrode surface of the substrate, and the display device held by the holding member And a drive circuit that applies a predetermined voltage to the pixel electrode and the conductive electrode when the display device is held by the holding member.

  The display system according to the present invention includes a display device that can be attached to and detached from the drive device, and a drive device that drives the display device. The display device includes a common electrode having a planar region, A first conductive electrode that conducts with a common electrode; an insulating member that covers one surface side of the region of the common electrode; and a display element that is bonded to the other surface side of the region of the common electrode, When a predetermined voltage is applied, an image corresponding to the predetermined voltage is displayed, and a display element that holds the displayed image even when no voltage is applied after the voltage is applied, and the display element A support member that supports the display element facing the region of the common electrode, and the driving device includes a substrate having an electrode surface that is a surface corresponding to the display element, and an electrode surface of the substrate. Table by the display element A pixel electrode provided corresponding to the pixel to be operated, a second conductive electrode that is electrically connected to the common electrode by being in contact with the first conductive electrode, the pixel electrode is in contact with the support member, and A driving circuit for applying a voltage corresponding to an image to be displayed to the display element via the pixel electrode and the second conductive electrode when the two conductive electrodes are in contact with the first conductive electrode; It is characterized by providing.

  According to the present invention, a configuration for writing an image on a display device, that is, a pixel electrode and a drive circuit can be provided separately from the display device. It is possible to reduce the number of parts of the display device.

[Embodiment]
FIG. 1 is a diagram showing a configuration of a display system according to an embodiment of the present invention. As shown in the figure, the display system 10 of this embodiment includes a display device 100, a drive device 200, and a data supply device 300. The display device 100 is planar so-called electronic paper. The display device 100 can be carried alone and can rewrite an image. The display device 100 is attached to the driving device 200 when rewriting an image. The drive device 200 drives the display device 100. The drive device 200 is detachably attachable to the display device 100. When the display device 100 is attached, the driving device 200 applies a voltage corresponding to image data representing an image to the display device 100. The driving device 200 may include a power source such as a battery, and may be operated by the driving device 200 or may be operated by being supplied with power from the data supply device 300. The data supply device 300 is connected to the driving device 200 by wire or wirelessly and supplies image data to the driving device 200. The data supply apparatus 300 is a personal computer, for example, and may be configured to allow the user to select or process image data.

  FIG. 2 is a diagram illustrating an appearance of the display device 100. As shown in the figure, the display device 100 includes a display area 100A and a non-display area 100B. The display area 100A is an area that forms a plurality of pixels and displays an image. That is, the display area 100A is an image display surface. The shape and area of the display area 100A are arbitrary, but for example, it is desirable that the display area is a rectangle of about A4 size (long side 297 mm, short side 210 mm) or B5 size (long side 257 mm, short side 182 mm). The non-display area 100B is an area where pixels are not provided, and is an area where no image is displayed.

FIG. 3 is a cross-sectional view showing the configuration of the display device 100 when the AA line shown in FIG. As shown in the figure, the display device 100 has four layers of an insulating sheet 110, a common electrode 120, a display element 130, and a support sheet 140. In addition, the display device 100 includes a sealing member 150 along end portions of the display element 130 and the support sheet 140. Since it is desirable that the display device 100 be bent as a whole, each member constituting the display device 100 desirably has flexibility (a property of being relatively easily bent).
For convenience of explanation, the surface on the insulating sheet 110 side of the display device 100 is referred to as “front surface” and the surface on the support sheet 140 side is referred to as “back surface”.

  The insulating sheet 110 is a planar member provided so as to cover the surface side of the common electrode 120, and is a sheet-like insulator that insulates the common electrode 120. It is sufficient that the insulating sheet 110 has a thickness capable of insulating the common electrode 120, but the thickness is about 100 μm. As the insulating sheet 110, it is desirable to use a colorless and transparent material that transmits visible light, such as PET (polyethylene terephthalate).

  The common electrode 120 is a planar electrode provided on at least the entire surface of the display region 100A. The common electrode 120 of the present embodiment is provided on a part of the non-display area 100B in addition to the entire surface of the display area 100A. As the common electrode 120, it is desirable to use a transparent conductive film such as ITO (indium tin oxide). The thickness of the common electrode 120 is about several μm.

  The display element 130 includes a plurality of pixels, and displays an image by setting each pixel to a predetermined gradation. The display element 130 is bonded to the back surface side of the common electrode 120 with an adhesive. The display element 130 according to the present embodiment displays an image corresponding to the applied voltage when a voltage is applied, and holds the displayed image even when no voltage is applied after the voltage is applied. , So-called memory (or bistability). The display element 130 according to the present embodiment is an electrophoretic element and includes a plurality of microcapsules 131. The microcapsule 131 encloses black fine particles charged to a certain polarity (positive or negative) and white fine particles charged to a polarity opposite to the black fine particles (positive or negative), Spherical particles filled with a dispersion medium having insulating properties, and the fine particles are moved according to the applied voltage, and exhibit gradation according to the voltage. The particle size of the microcapsule 131 is about 60 μm.

The support sheet 140 is a sheet-like member that supports the display element 130 from being peeled off from the back surface side of the display element 130. Further, the support sheet 140 has a function of protecting the display element 130. For example, PET is used as the support sheet 140, and the thickness thereof is about several μm.
The sealing member 150 is a member that seals the display element 130, and is provided along the ends of the display element 130 and the support sheet 140. For example, an acrylic resin or an epoxy resin is used as the sealing member.

As shown in FIG. 3, the common electrode 120 has a portion where the display element 130 is not bonded and is not covered with the support sheet 140. That is, this portion is exposed without being insulated. This part is hereinafter referred to as “conduction part”. The conducting portion is a region provided for conducting with a conducting electrode described later, and is an example of the “first conducting electrode” in the present invention.
As described above, the common electrode 120 includes a region where the display element 130 is provided and a conduction portion. The region where the display element 130 is provided is a region overlapping the display surface. That is, the region where the display element 130 is provided is included in the display region 100A, and the conductive portion is included in the non-display region 100B.

  FIG. 4 is a diagram illustrating an internal configuration of the driving device 200. In addition, the broken line shown in the figure represents the display device 100 in a state of being inserted into the driving device 200. In this state, the display device 100 has the front surface in the direction of the arrow R and the back surface in the direction of the arrow L. In the following, the direction of the arrow R is “right”, the direction of the arrow L is “left”, the direction of the arrow U is “up”, and the direction of the arrow D is “down”. However, the attitude of the driving device 200 is not limited to this example, and it is also possible to use one of the left and right sides upward here.

  As shown in FIG. 4, the driving device 200 includes a slot 210, a first substrate 220, a second substrate 230, a biasing member 240, and a holding member 250. The slot 210 is an opening for inserting the display device 100 into the drive device 200 and mounting it. Note that the slot 210 may be provided with a door that opens and closes. The first substrate 220 is a substrate for mounting a pixel electrode 221 and a conductive electrode 222 described later. As the first substrate 220, for example, a glass plate is used. The second substrate 230 is a substrate for mounting the drive circuit 231. The drive circuit 231 is a circuit that acquires image data supplied from the data supply device 300 and supplies a voltage corresponding to the image data. The drive circuit 231 is electrically connected to the pixel electrode 221 and the conduction electrode 222, and applies a voltage corresponding to the image data to the pixel electrode 221 and the conduction electrode 222.

  The urging member 240 is a member that urges the display device 100 to contact the right direction, that is, the first substrate 220 when the display device 100 is mounted. That is, the urging member 240 is present at a predetermined interval between the pixel electrode 221 and the conductive electrode 222 so as to allow the display device 100 to enter before the display device 100 is mounted. The urging member 240 obtains a force that is pressed by an elastic member such as a spring and urges the display device 100. The biasing member 240 is preferably in contact with the support sheet 140 of the display device 100 and the pixel electrode 221 when the display device 100 is biased. At this time, it is more desirable that the urging member 240 urges the entire surface of the display device 100 with a uniform force.

  The holding member 250 is a member that holds the display device 100 so that the display device 100 does not move when the display device 100 is mounted and a voltage is applied to the display device 100. When the display device 100 is held, the holding member 250 is provided at a position where the support sheet 140 and the pixel electrode 221 are in contact with each other and the conduction portion and the conduction electrode 222 are in contact with each other. Further, the holding member 250 may have a mechanism such that at least a part of the display device 100 moves above the slot 210 when the rewriting of the display device 100 is completed and the user tries to take it out. . Such a mechanism is realized by, for example, pushing up the holding member 250 by an elastic member such as a spring.

  FIG. 5 is a diagram schematically illustrating the configuration of the first substrate 220, and is a diagram illustrating a surface of the first substrate 220 that is in contact with the display device 100. As described above, the first substrate 220 has a surface on which the pixel electrode 221 and the conduction electrode 222 corresponding to the common electrode 120 and the display element 130 of the display device 100 are provided. This surface is hereinafter referred to as an “electrode surface”. As shown in the figure, the first substrate 220 is provided with a plurality of pixel electrodes 221, conductive electrodes 222, and connection terminals 223. The connection terminal 223 is electrically connected to the wirings 227, 228, and 229. In the present embodiment, the pixel electrodes 221 are formed in a matrix over a plurality of rows and a plurality of rows.

  The pixel electrode 221 is an electrode provided on the electrode surface corresponding to the pixel displayed by the display element 130. That is, the number of pixel electrodes 221 is the same as the number of pixels of the display element 130. The area of the electrode surface where the pixel electrode 221 is provided overlaps the display area 100A when the display device 100 is mounted. The conducting electrode 222 is an electrode provided on the electrode surface corresponding to the conducting portion of the common electrode 120, and is an example of the “second conducting electrode” in the present invention. The conductive electrode 222 overlaps and contacts the conductive portion of the common electrode 120 when the display device 100 is mounted. The connection terminal 223 is electrically connected to the drive circuit 231, and applies a voltage supplied from the drive circuit 231 to the pixel electrode 221 and the conduction electrode 222 through the wirings 227, 228, and 229.

  FIG. 6 is a diagram showing the configuration of the electrode surface of the first substrate 220 in more detail, and is an enlarged view showing a part of the configuration shown in FIG. As shown in the drawing, the first substrate 220 is provided with scanning lines 224, data lines 225, and switching elements 226. The scanning line 224, the data line 225, and the switching element 226 are patterned on the electrode surface of the first substrate 220 and have a thin film shape. The scan line 224 is a conductor extending in the row direction of the matrix formed by the pixel electrode 221 and is electrically connected to the wiring 227. A plurality of scanning lines 224 are provided so that each is parallel to each other. The data line 225 is a conductor extending so as to intersect the scanning line 224 in the column direction of the matrix formed by the pixel electrode 221. A plurality of data lines 225 are provided so as to be electrically connected to the wiring 228 and to be parallel to each other. The switching element 226 is an element provided so as to correspond to the intersection of the scanning line 224 and the data line 225. That is, the number of switching elements 226 is the same as the number of pixel electrodes 221. The switching element 226 switches on / off of voltage application to the pixel electrode 221 in accordance with a voltage applied between the scanning line 224 and the data line 225. As the switching element 226, for example, a TFT (Thin Film Transistor) is used.

The configuration of the display system 10 is as described above. Under this configuration, the user uses the display device 100. Since the display device 100 is detachable from the driving device 200, the display device 100 can be used separately from the driving device 200. That is, the user can carry the display device 100 freely.
On the other hand, when the user intends to rewrite the image displayed on the display device 100, the user attaches the display device 100 to the drive device 200. At this time, the user wears the display device 100 by inserting it into the slot 210.

  When the display device 100 is inserted, the holding member 250 prevents the display device 100 from moving downward in the driving device 200. Thereby, the display apparatus 100 is hold | maintained so that it may not move to an up-down direction. Further, when the display device 100 does not move downward, the display device 100 is urged by the urging member 240 in the right direction, that is, in the direction in which the pixel electrode 221 and the conductive electrode 222 are present. That is, at this time, the urging member 240 holds the display device 100 so as not to move in the left-right direction. Therefore, the display device 100 is held so as not to move in the vertical direction and the horizontal direction by being held by the holding member 250 and being biased by the biasing member 240.

  When the display device 100 is thus mounted, in the driving device 200, the driving circuit 231 starts an operation for rewriting. At this time, the driving circuit 231 performs driving for supplying a voltage signal to each of the scanning line 224, the data line 225, and the conduction electrode 222 so that the pixel electrode 221 generates a predetermined potential difference with respect to the common electrode 120. Do. The potential difference here is determined according to the gradation to be displayed on the pixel corresponding to each pixel electrode 221. That is, the voltage applied to each pixel electrode 221 is determined according to the image to be displayed by driving.

  When the voltage is applied in this way, the display device 100 displays an image corresponding to the applied voltage. That is, in the display device 100, the display surface is rewritten. When the rewriting is completed, the driving device 200 cancels the urging by the urging member 240 so that the display device 100 can be taken out. At this time, the driving device 200 may push up the holding member 250 as described above to facilitate removal of the display device 100. By performing such an operation, it is possible to notify the user that the rewriting has been completed.

  As described above, in the display system 10 of this embodiment, the display device 100 can be rewritten, and the display device 100 and the driving device 200 can be separated. Therefore, the display device 100 can be used for display alone. The display device 100 itself includes only a so-called front plane portion, and does not include a so-called back plane portion (the first substrate 220 and the second substrate 230 in the present embodiment). Therefore, the display device 100 can reduce the number of parts as compared with electronic paper having a configuration having both a front plane portion and a back plane portion.

  In general, the backplane part is heavier and thicker than the front plane part. For example, the glass substrate constituting the backplane portion usually has a thickness of at least about 500 μm and a specific gravity of about 2.5. Therefore, the back plane part occupies most of the weight and thickness in the electronic paper configured to have both the front plane part and the back plane part. On the other hand, the display device 100 of the present embodiment has four layers of an insulating sheet 110 (about 100 μm), a common electrode 120 (about several μm), a display element 130 (about 60 μm), and a support sheet 140 (about several μm). However, if there are only these four layers, it is at most about 180 μm, which is less than 200 μm. Therefore, according to the display device 100 of the present embodiment, it can be expected that both the weight and the thickness are significantly reduced as compared with the electronic paper configured to have both the front plane portion and the back plane portion.

  According to the prototype of the inventor of the present invention, the thickness of the front plane portion created in the manner of the display device 100 described above was about 200 μm and the weight was about 10 g. On the other hand, the electronic paper in which the front plane portion and the back plane portion are integrated has a thickness of about 700 μm and a weight of about 67 g, even if the weight of the battery is excluded.

  Further, the glass substrate constituting the backplane portion is relatively easily damaged by an impact such as dropping, and cannot be bent. In addition, the drive circuit that drives the display element may be disabled due to bending or impact. On the other hand, since the display device 100 according to the present embodiment does not include such a glass substrate or a driving circuit, the possibility of being damaged or becoming inoperable can be significantly reduced as compared with electronic paper including these. It is.

[Modification]
The present invention can be implemented in a form different from the above-described embodiment. The following modifications are examples of modifications applicable to the present invention. In addition, these modifications may be implemented by appropriately combining each as required.

(1) Modification 1
In the present invention, the conductive electrode (first conductive electrode) on the display device side may not be provided integrally with the common electrode 120 as in the above-described embodiment. For example, the first conductive electrode and the common electrode may be electrically connected by wiring. In such a configuration, the first conductive electrode and the common electrode may not be adjacent to each other and may be separated from each other. Therefore, when the first conductive electrode and the common electrode are provided integrally, In comparison, it is possible to change these arrangements without restriction.
On the other hand, when the common electrode and the first conductive electrode are provided integrally, the configuration for conducting them becomes unnecessary, so when the common electrode and the first conductive electrode are provided separately. In comparison, there is an effect that the configuration can be simplified.

(2) Modification 2
In the above-described embodiment, one conductive portion (first conductive electrode) is provided in the display device, but a plurality of conductive portions may be provided. In addition, the position of the conducting portion is not limited as long as it can conduct with the common electrode.

  FIG. 7 is a diagram illustrating a first example of the configuration of the conduction portion. In the following drawings, parts having the same configurations as those of the above-described embodiment are denoted by the same reference numerals. In this example, the common electrode 120 is provided on the front surface side of the display element 130, and the conduction portion 121 is provided on the back surface side of the display element 130. The common electrode 120 and the conducting portion 121 may be provided separately. For example, one conductive film is bent at the end of the display element 130, the front side is the common electrode 120, and the back side is the conducting portion 121. Also good. In the case of the configuration as in this example, the conductive electrode 222, that is, the electrode corresponding to the second conductive electrode needs to be provided at a position in contact with the conductive portion 121. For example, the driving apparatus corresponding to this example may have a configuration in which the second conduction electrode is provided on the biasing member 240 in the configuration illustrated in FIG. When the conducting portion is configured as in this example, the area corresponding to the non-display area 100B described above can be reduced, and the ratio of the display surface can be increased. For example, according to this example, it is possible to make all of one surface of the display device a display region, and to eliminate a region where an image is not displayed (so-called frame region), and a paper-like display device can be obtained.

  FIG. 8 is a diagram illustrating a second example of the configuration of the conduction portion. In this example, a conducting portion 410 is provided on a side where the rectangular common electrode 430 is provided, and a conducting portion 420 is provided on a side opposite to the side. In addition, in the same figure, although the conduction | electrical_connection part 410 is provided in the lower side and the conduction | electrical_connection part 420 is provided in the upper side, you may provide these in a right-and-left side. Further, the conducting portions 410 and 420 may be provided with the same length as the side of the common electrode 430 as shown in FIG. 8A, or from the side of the common electrode 430 as shown in FIG. 8B. May be short. Further, in any of the configurations shown in FIG. 8, it is more desirable that the conducting portions 410 and 420 are provided at positions that are symmetric with respect to the center of the common electrode 430 (point O in the drawing).

  FIG. 9 is a view showing a second conductive electrode corresponding to the conductive portion of this example, and corresponds to the configuration of FIG. 8B. In the configuration of FIG. 9A, two conductive electrodes 510 and 520 are provided above and below the pixel electrode 530 so as to correspond to the conductive portions 410 and 420, respectively, and the configuration of FIG. The conductive electrode 510 is provided and the conductive electrode 520 is not provided.

As shown in FIG. 8, when the conductive portions 410 and 420 are provided symmetrically with respect to the center of the common electrode 430, the display device may be inserted without considering the upper and lower sides of the display device. Improved usability. In this case, it is sufficient that either one of the conducting portions 410 and 420 is conducted. Therefore, the second conducting electrode may be configured as shown in FIG. 9B.
However, when the configuration of FIG. 9A is used, the common electrode 430 is electrically connected to both of the conductive portions 410 and 420, and therefore, compared to the case where the common electrode 430 is electrically connected to only one as shown in FIG. 9B. Is more stable from the upper side to the lower side, and there is another effect that the difference in potential between the upper side and the lower side becomes small.

  In this modification, the shape of the common electrode is not limited to a rectangle. The common electrode may have a shape in which the region corresponding to the display surface is symmetric, that is, a shape that is symmetric with respect to the center point.

(3) Modification 3
The biasing member 240 of the above-described embodiment is an example of a biasing unit of the present invention. However, since the urging member 240 holds the display device 100 so as not to move in the left-right direction by being urged, it can be regarded as an example of the holding member of the present invention. Further, the biasing member 240 and the holding member 250 can be regarded as functioning as means for holding the display device 100 by cooperating.

  Note that the biasing means of the present invention is not limited to the biasing member 240 that biases by pressing. The urging means of the present invention may be, for example, a device that presses the display device to the pixel electrode side by blowing air, or the display device is adsorbed to the pixel electrode side by sucking air from the pixel electrode side. It may be a thing. In short, the urging means of the present invention is not particularly limited as long as it generates a force such that the support member of the display device and the pixel electrode are brought into close contact with each other.

  However, in the present invention, the biasing means is not an essential configuration. This is because if there is another alternative means for preventing the display device from moving during rewriting, the urging means is unnecessary and the user may hold down the display device. However, it is not preferable that the display device can easily move at the time of rewriting because the voltage application to the display element may be insufficient or the position where the voltage is applied may be shifted.

(4) Modification 4
In the present invention, it is desirable that the timing of rewriting, that is, the timing at which the drive circuit starts to apply voltage is after the display device is held so as not to move. Such timing may be specified by the user using the data supply device 300 described above, or an operation element (button or the like) for the user to specify the timing is provided in the driving device, and according to the operation of this operation element. It may be decided.

  Moreover, the drive device according to the present invention may be configured to include a detection unit that detects that the display device is held so as not to move, and to start application of a voltage after detection by the detection unit. In this way, rewriting can be started at an appropriate timing without the user specifying it. As such a detection means, for example, a device that electrically detects that the second conductive electrode and the common electrode are conductive by measuring current or voltage can be used. Further, the drive device according to the present invention detects the position of the display device by a sensor, and starts applying the voltage when the display device has existed at a predetermined position without moving for a predetermined time or more. Also good.

(5) Modification 5
The drive device according to the present invention may include a reading unit that reads an image and generates image data representing the read image. As such reading means, for example, a line sensor or an area sensor using an image sensor such as a CCD (Charge Coupled Device) can be used. Note that the reading unit of the present invention is configured separately from the driving device, and may be configured to supply the generated image data to the driving device.

  The reading means of the present invention is configured to read a predetermined position of the display device, for example. In this case, the “predetermined position” refers to a position where information that can specify an image to be displayed after rewriting on the display device is drawn. Such information is, for example, the page number of a certain document. This example will be described based on the embodiment described above. That is, the data supply device 300 stores in advance image data representing a document composed of images of a plurality of pages for each page, and the image data is configured such that page numbers are drawn at predetermined positions. Yes. The reading unit reads the page number displayed on the display device 100 attached to the driving device 200 and supplies the image data to the data supply device 300. The data supply device 300 recognizes a page number using, for example, an OCR (Optical Character Recognition) function, and supplies image data of the page number next to the page number. The driving device 200 applies a voltage corresponding to the image data (that is, image data corresponding to the read page number) to drive the display device 100. In this way, the driving device 200 can be rewritten to an image corresponding to the read information even if the image to be displayed next is not designated by the user.

  In the present invention, it is possible to cause the drive device according to the present invention to function as a copying apparatus by providing reading means. For example, when the driving device reads a document with a reading unit, the read image data is represented by gradations corresponding to each pixel electrode, and a voltage corresponding to the gradation is applied to each pixel electrode. An image representing the read document can be displayed on the display device.

  FIG. 10 is a diagram illustrating the reading means of the present invention, and is a view when the reading means is provided integrally with the driving device. The drive device 200a shown in the figure includes a conveyance roller 260 and a line sensor 270 in addition to the configuration shown in FIG. The conveyance roller 260 is a member that conveys a document at a constant speed. The line sensor 270 reads the document conveyed by the conveyance roller 260 and generates image data representing the read document. Note that the original document here may be paper of the same size as the display device, but may be a display device when there are a plurality of display devices.

  When copying, the user inserts a document into the slot 210 of the driving device 200a. The driving device 200 a reads the document with the line sensor 270 while transporting the document downward with the transport roller 260. When the driving device 200a reads the document and generates image data, the driving device 200a transports the document upward by the transport roller 260 and causes the user to take out the document. Thereafter, when the display device is inserted, the driving device 200a applies a voltage corresponding to the image data generated in advance to the display device to display an image corresponding to the document.

(6) Modification 6
The display device and the driving device according to the present invention may include identification means for identifying individual devices and recognition means for recognizing the identification means. For example, an RFID (Radio Frequency IDentification) tag storing identification information may be provided on the display device, and a reader for recognizing the RFID tag may be provided on the driving device. In this way, it is possible to display an image corresponding to the identification information of each display device.
If the information for identifying each device is printed at a predetermined position of the display device, the above-described reading unit can be used as the recognition unit.

(7) Modification 7
In the above-described embodiment, the pixel electrode 221 and the conductive electrode 222 are formed on the first substrate 220 that is a glass plate, and are formed so as to form the same plane. However, the pixel electrode and the second conductive electrode of the present invention may be formed so that each has the same curved surface. In this case, the display device may be bent along the curved surface formed by the pixel electrode and the second conductive electrode when being rewritten.

(8) Modification 8
The display device 100 described above can display images on both the front surface and the back surface by configuring the insulating sheet 110, the common electrode 120, and the support sheet 140 with transparent members. In this case, the image displayed on the back surface is an image obtained by inverting the gradation of the image displayed on the front surface. If there is no need to display images on both sides, either the insulating sheet 110, the common electrode 120, or the support sheet 140 is made of an opaque member, or is opaque on either the front side or the back side. One layer of another member may be provided.

(9) Modification 9
The display element of the present invention is not limited to the electrophoretic element described above. The display element of the present invention may be a display element using cholesteric liquid crystal, for example.
In the present invention, the number of pixel electrodes, that is, the number of pixels is arbitrary. In addition, the arrangement of the pixel electrodes is not limited to a matrix, and may be an arrangement that performs so-called segment display, for example.

The figure which shows the structure of the display system which concerns on this invention Figure showing the appearance of the display device Sectional drawing which shows the structure of a display apparatus The figure which shows the internal structure of a drive device The figure which shows the composition of the 1st substrate The figure which shows the composition of the 1st substrate Diagram showing the configuration of the conduction part Diagram showing the configuration of the conduction part The figure which shows the 2nd conduction electrode The figure which shows the reading means of this invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Display system, 100 ... Display apparatus, 110 ... Insulating sheet, 120 ... Common electrode, 130 ... Display element, 140 ... Support sheet, 200 ... Drive apparatus, 210 ... Slot, 220 ... First substrate, 221 ... Pixel electrode, 222 ... conductive electrode, 230 ... second substrate, 231 ... drive circuit, 240 ... biasing member, 250 ... holding member, 300 ... data supply device

Claims (7)

A display system having a display device detachable from a drive device and a drive device for driving the display device,
The display device
A common electrode having a planar region;
A first conducting electrode conducting with the common electrode;
An insulating member covering one surface side of the region of the common electrode;
A display element that is bonded to the other surface side of the region of the common electrode, and displays an image according to the predetermined voltage when a predetermined voltage is applied, and the voltage is applied after the voltage is applied. A display element for holding a displayed image even when not applied,
A support member that supports the display element facing the region of the common electrode through the display element,
The driving device includes:
A substrate having an electrode surface which is a surface corresponding to the display element;
A pixel electrode provided on the electrode surface of the substrate corresponding to a pixel displayed by the display element;
A second conductive electrode that is conductive with the common electrode by contacting the first conductive electrode;
When the pixel electrode is in contact with the support member and the second conductive electrode is in contact with the first conductive electrode, a voltage corresponding to an image to be displayed is applied to the display element and the pixel electrode and the And a driving circuit for applying the second conductive electrode through the second conductive electrode.   The display system according to claim 1, wherein the common electrode and the first conductive electrode are integrally formed of a conductive film.   The display system according to claim 1, wherein the driving device includes an urging unit that urges the pixel electrode and the support member to come into close contact with each other. The common electrode has the region that is symmetrical with respect to the center;
The said 1st conduction | electrical_connection electrode has the 1st and 2nd conduction | electrical_connection part electrically connected with the said common electrode in the position where each is symmetrical with respect to the center of the said area | region. Display system. A detecting means for detecting that the second conductive electrode and the common electrode are conductive;
The display system according to claim 1, wherein the drive circuit applies a voltage when continuity is detected by the detection unit. A reading unit that reads the image and generates image data representing the read image;
The display system according to claim 1, wherein the driving circuit applies a voltage according to image data generated by the reading unit. A display device detachable from the device itself, a holding member for holding the display device having a display surface and a common electrode corresponding to the display surface so as not to move,
A substrate having an electrode surface at a position corresponding to the display surface of the display device held by the holding member;
A pixel electrode provided on an electrode surface of the substrate;
A conducting electrode that conducts with the common electrode of the display device held by the holding member;
And a driving circuit that applies a predetermined voltage to the pixel electrode and the conductive electrode when the display device is held by the holding member.

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