JP2010284075A - Electric double-layer capacitor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To employ a power supply which does not deteriorate in performance and has durability as a power supply for information display apparatus. <P>SOLUTION: An active material forming material 1 containing at least an electrode active material and a binder are supplied between a drag 2 and a cope 3, where mutually formed irregular patterns 4 and 5 are arranged face to face. After the active material forming material is pressed by the drag and the cope, the drag and the cope are separated and an active material 6 for an energy storage device is produced. Using the active material for the energy storage device as an active material layer, a current collector 7 is fixed to one side thereof and an electrode 10 for the energy storage device is formed. An electric double-layer capacitor is formed using the electrode for the energy storage device made in this process. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an information display system device comprising a portable information display device for displaying information and a charging device for charging the information display device.

  In recent years, it has become common to handle information electronically. However, as a method for visually displaying such electronic information, a method of printing on paper is still widely used. This is because the information printed on paper is easy to see and handle. However, the information printed on the paper is in a state of being fixed on the paper, and it is difficult to rewrite and erase the information and cannot be used as electronic information. In recent years, the amount of paper consumption has increased year by year due to the printing of information on paper, which is undesirable from the viewpoint of resource protection, and has caused environmental problems.

  Therefore, there is a demand for a display medium that can use information such as rewritable information as electronic information while having the advantages of paper. As a display medium that responds to this demand, electronic paper that is easy to see, rewritable, requires little energy to maintain display, and is excellent in portability is expected. Various information display devices using electronic paper are expected. Proposed. As electronic paper, various methods such as a twist ball method, an electrophoresis method, and an electrophoretic method have been studied.

  However, since electronic paper can hold display information in a non-powered state, power consumption is small, but a power source for driving is necessary. Many devices using conventional electronic paper as a power source use secondary batteries. However, since the secondary battery cannot flow a large current, it takes a long time to charge, and lacks convenience, such as being unable to respond immediately when the battery runs out in an emergency. In addition, since the performance of a secondary battery deteriorates when charging and discharging are repeated, the battery has a service life. However, a display device using electronic paper needs to ensure a long battery life so that it can withstand long-term use as an information display medium that replaces paper.

  On the other hand, in actual use, considering the case where information display devices using such electronic paper are replaced with conventional paper and used to display conference materials, browse news on the move, etc., at most tens of pages If the minute information can be displayed, the purpose can be sufficiently achieved, and the required power is not so large. For this reason, it is not always necessary to give a large power to the power source of the information display device. Instead, convenience can be ensured if the charging can be completed in a short time when necessary. Furthermore, when distribution of materials to a large number of people in a conference, distribution of news to a large number of people, and the like, it is necessary to efficiently charge a plurality of information display devices and to efficiently distribute various types of information.

  From the above, the information display device can be charged at high speed to shorten the charging time, and the information display device does not require a large amount of power, while having durability that enables repeated use over a long period of time, There is a need to efficiently charge an information display device and efficiently transmit and receive data.

  By the way, in the electronic paper display system apparatus described in Patent Document 1 below, information is displayed using a nonvolatile flexible sheet-like display device, and charging of the sheet-like display device is performed using electromagnetic induction. Proposed. Similarly, the information display device described in Patent Document 2 below displays information using a non-volatile flexible sheet-like display device and charges the sheet-like display device using electromagnetic induction. Proposed.

JP 2005-316672 A JP 2004-350439 A

  However, the devices described in Patent Document 1 and Patent Document 2 cannot be said to both efficiently charge an information display device and efficiently transmit and receive data.

  Therefore, the first object of the present invention is to enable high-speed charging of the information display device, to shorten the charging time, and to enable repeated use over a long period of time without requiring large power for the information display device, An object is to efficiently charge an information display device and efficiently transmit and receive data.

By the way, in the portable information display device of this type of information display system apparatus, a liquid crystal display has been conventionally used for the reason that the display of the information display unit can be thinned. However, the liquid crystal display has drawbacks such as a narrow viewing angle, a backlight and a large power consumption, and is not necessarily optimal as a display for an information display unit.
Accordingly, a second object of the present invention is to optimize the display of the information display unit provided in the information display device.

In information display devices, conventionally, secondary batteries are mainly used as power sources. However, since it is difficult to flow a large current, the secondary battery has a drawback that it takes time to charge, and the performance deteriorates due to repeated charging and discharging.
Accordingly, a third object of the present invention is to employ a durable power source that does not deteriorate in performance as a power source for an information display device.

Conventionally, in an information display system device including an information display device and a charging device, data transmission / reception by electromagnetic induction is performed one-to-one between a data transmission side and a data reception side. For this reason, when data is transmitted / received to / from a plurality of information display devices, data must be transmitted / received separately, resulting in inefficiency.
Accordingly, a fourth object of the present invention is to construct a system that enables batch data transmission / reception to / from a plurality of information display devices.

  The fifth object of the present invention is to further enhance the convenience of the information display device.

By the way, in an information display system device including an information display device that displays information on a display of an information display unit and a charging device that charges the information display device, conventionally, charging of the information display device using a charging device by electromagnetic induction is performed. Some do. However, in this type of information display system device, when a plurality of information display devices are being charged by electromagnetic induction, if the information display device is inserted into or removed from the charging device, the magnetic field in the electromagnetic induction changes and the magnetic The state of the circuit changes and it becomes impossible to charge in the optimum state.
Accordingly, a sixth object of the present invention is to enable power supply in an optimum state even when the information display device is inserted into and removed from the charging device during charging of a plurality of information display devices. To build a system.

Conventionally, an information display system device including an information display device and a charging device cannot arbitrarily distribute different data to a plurality of information display devices.
Accordingly, a seventh object of the present invention is to enable arbitrarily distributing information having different contents to a plurality of information display devices.

The present invention is an information display system device for achieving the first object described above,
A portable information display device comprising an information display unit for displaying information, a data transmission / reception control unit, a charge / discharge control unit, and a data communication / control unit having a power storage unit;
A data transmission / reception control unit for controlling transmission / reception of data to / from the information display device, a data communication / power supply unit having a power supply control unit for controlling power supply to the information display device, a power supply unit, and an operation unit. A charging device that transmits and receives data simultaneously with charging by electromagnetic induction with respect to the information display device;
It is characterized by comprising.

  And when charging with respect to an information display apparatus by electromagnetic induction, data transmission / reception is performed simultaneously. Transmission data from the charging device to the information display device is mainly data of contents displayed on the information display device. On the other hand, transmission data from the information display device to the charging device includes a communication ID for individually recognizing a plurality of information display devices, a charging status of each information display device, a data reception status, and the like.

  The invention described in claim 2 is the information display system device according to claim 1, wherein a non-volatile electronic display element is used for the information display unit in order to achieve the second object described above. To do. In a portable information display device, information is displayed using a nonvolatile electronic display element.

  According to a third aspect of the present invention, there is provided the information display system device according to the first or second aspect, wherein the electric double layer is provided in the power storage unit included in the data communication / control unit in order to achieve the third object. A capacitor is used. The electric double layer capacitor is used as a power source for the information display device.

  According to a fourth aspect of the present invention, there is provided the information display system device according to the third aspect, wherein the lower mold in which the concavo-convex patterns formed to face each other are arranged to achieve the third object described above. An active material forming material containing at least an electrode active material and a binder is supplied between the upper die, and after the active material forming material is pressed between the lower die and the upper die, the lower die And the upper mold are peeled off to produce an active material for an electricity storage device. The active material for the electricity storage device is used as an active material layer, and a current collector is fixed on one side to produce an electrode for the electricity storage device. The electric double layer capacitor is formed using a device electrode.

  According to a fifth aspect of the present invention, there is provided an information display system device according to the third aspect, wherein at least the electrode active material and the binder are formed on the concave / convex pattern formed on the lower mold in order to achieve the third object. After the upper mold is pressed against the active material forming material until the active material forming material enters the concavo-convex pattern formed in the upper mold, the upper mold is then supplied. And the lower mold are peeled off to produce an active material for an electricity storage device. The active material for the electricity storage device is used as an active material layer, and a current collector is fixed on one side to produce an electrode for the electricity storage device. The electric double layer capacitor is formed using a device electrode.

  The invention according to claim 6 is the information display system device according to claim 3, wherein at least the electrode active material and the binder are formed on the concave-convex pattern formed on the mold in order to achieve the third object. A first step in which an active material forming material containing the first material is supplied; a second step in which a current collector is fixed to the active material forming material; and a first step in which the mold is peeled from the active material forming material. An electrode for an electricity storage device is produced from the three steps, and the electric double layer capacitor is formed using the electrode for the electricity storage device.

  The invention according to claim 7 is the information display system device according to any one of claims 1 to 6, wherein the charging device is generated in the charging device in order to achieve the fourth object described above. A display device installation section for installing a plurality of the information display devices is provided so as to cross the power supply magnetic flux and the data communication magnetic flux. When charging the information display device, install multiple information display devices in the display device installation section of the charging device, detect the installation and transmit the optimal amount of power, and the optimal data transmission / reception status And charging and data transmission / reception for a plurality of information display devices at once.

  The invention according to claim 8 is the information display system apparatus according to claim 7, wherein the information display device is formed in a sheet shape in order to achieve the fifth object described above. Then, when charging the information display device, a plurality of information display devices are placed horizontally or vertically on the charging device.

  The invention according to claim 9 is the information display system device according to claim 7 or 8, wherein the charging device detects insertion / removal of the information display device in order to achieve the sixth object described above. And a magnetic field comparison unit. When the information display device is inserted into and removed from the charging device, the magnetic field comparison unit detects the insertion and removal of the information display device and controls the magnetic flux of electromagnetic induction.

  The invention described in claim 10 is the information display system apparatus according to any one of claims 1 to 9, wherein the communication ID is assigned to each of the information display devices in order to achieve the seventh object described above. It is characterized by having. And when distributing information to an information display device, it identifies by detecting communication ID of each information display device, and distributes information having different contents to a plurality of information display devices.

  According to the first aspect of the invention, since charging and data transmission / reception are simultaneously performed on the information display device by electromagnetic induction, the information display device can be charged at high speed, and the charging time is shortened. The information display device can be charged efficiently and at the same time the data can be efficiently transmitted and received, thereby improving the convenience.

  According to the second aspect of the present invention, since the nonvolatile electronic display element is adopted as the display of the information display unit instead of the conventional liquid crystal display, power is required only when the display screen is rewritten, and the information that has been rewritten once. Can be held without a power source, so that the power required for the display can be reduced compared to a liquid crystal display. In addition, the display can ensure a wide viewing angle. Furthermore, the information display device can be made thinner and easier to handle by making the display into a thin sheet. Thereby, the information display apparatus which optimized the display of the information display part is realizable.

  According to the third aspect of the present invention, since an electric double layer capacitor is used as the power source of the information display device in place of the conventionally used secondary battery, a large current can be passed to the power source and rapid charging can be performed. This makes it possible to shorten the charging time. Further, since deterioration due to repeated charge / discharge hardly occurs, the durability of the power source can be improved, and a maintenance-free information display device for the power source can be realized.

  According to the invention described in claims 4 to 6, since the electric double layer capacitor is used as the power source of the information display device, the internal resistance of the active material layer itself is low and the electrical connection between the active material layer and the current collector is also good. Thus, an information display device using a power supply having high output characteristics can be realized.

  According to the seventh aspect of the invention, when charging the information display device, a plurality of information display devices are installed in the display device installation section of the charging device, and the plurality of information display devices are collectively and efficiently processed. Data can be sent and received simultaneously with charging.

  According to the invention described in claim 8, since the information display device is formed in a sheet shape, the information display device is easy to handle, and is installed on the charging device to facilitate charging of the plurality of information display devices. The convenience can be further improved.

  According to the ninth aspect of the present invention, when the information display device is inserted into and removed from the charging device, the magnetic field comparison unit detects the insertion and removal of the information display device and controls the magnetic flux of electromagnetic induction. It is possible to continue the efficient charging while adjusting to a proper power transmission state, and it is possible to continue the data transmission / reception by adjusting to an optimal data transmission / reception state.

  According to the tenth aspect of the present invention, when distributing information to information display devices, the information is selectively distributed to a plurality of information display devices, and information of different contents can be arbitrarily assigned to each information display device. Can be displayed.

1 is a configuration block diagram of an information display system device according to the present invention. It is a perspective view which shows the information display system apparatus which installed the some information display apparatus in the charging device, (A) is the example which installed the information display apparatus in the flat-stacked state, (B) is the example installed in the vertical installation state Show. It is a figure which shows an example of charge and data transmission between a some information display apparatus and charging equipment. It is a figure which shows the structural example of the electric double layer capacitor used for the power supply of an information display apparatus as an electrical storage part. It is a manufacturing process figure of an example of the electrode for electric double layer capacitors. It is a manufacturing process figure of another example of the electrode for electric double layer capacitors. It is a manufacturing process figure of another example of the electrode for electric double layer capacitors.

The best mode for carrying out the present invention will be described below with reference to the drawings.
FIG. 1 shows a configuration block diagram of an information display system apparatus according to the present invention. As shown in the figure, the information display system apparatus includes a portable information display device 100 and a charging device 200.

  The information display device 100 includes a data communication / control unit 30 and an information display unit 40. The data communication / control unit 30 includes a data transmission / reception control unit 31 and a charge / discharge control unit 32, and one data transmission / reception control unit 31 is connected to a storage unit 34 via a storage control unit 33, while an antenna 35. A power source 36 is connected to the other charge / discharge control unit 32 together with its antenna 35. In addition, the information display unit 40 includes a display control unit 41 connected to the storage control unit 33 of the data communication / control unit 30, and a display 42 and a display for displaying information connected to the display control unit 41. An operation unit 43 is provided.

  On the other hand, the charging device 200 includes a data communication / power supply unit 50, a power source 56, an operation unit 60, and an external interface unit 70. The data communication / power supply unit 50 includes a data transmission / reception control unit 51 that controls transmission / reception of data to / from the information display device 100 and a power supply control unit 52 that controls supply of power to the information display device 100. The transmission / reception control unit 51 is connected to the storage unit 54 via the storage control unit 53, and is connected to the antenna 55. The other power supply control unit 52 is connected to the power supply 56 together with the antenna 55. . The charging device 200 further includes a magnetic field comparison unit 58 that detects insertion / removal of the information display device 100 in the data communication / power supply unit 50.

  The operation unit 60 includes a display unit 61 and an operation unit 62 and is connected to the data transmission / reception control unit 51 and the power supply control unit 52. The external interface unit 70 includes an external interface 71 and an external communication control unit 72, and the external interface 71 is connected to the data transmission / reception control unit 51 via the external communication control unit 72.

  In the information display system apparatus shown in FIG. 1, the control unit is divided into several parts and individually performs various types of control. It is good also as a structure which performs whole control.

  In the information display device 100, the storage unit 34 of the data communication / control unit 30 includes a rewritable nonvolatile memory, and stores various data such as received data, operation information, and communication ID.

  The antenna 35 of the information display device 100 may be a loop antenna and may be an air core. However, by arranging a magnetic material such as ferrite inside, the concentration of magnetic flux can be increased and a more effective antenna can be obtained. The antenna material can be improved in magnetic properties by using a metal or organic material having a low resistivity. The antenna 35 of the information display apparatus 100 may be configured as a bi-directional winding so that the generation of a magnetic field due to the antenna induced current is suppressed and the influence on the charging side is eliminated as much as possible. And a large loop antenna is installed in the whole apparatus periphery, a small loop antenna is installed in the arbitrary positions of an apparatus, and a some loop antenna is installed in the arbitrary positions of an apparatus.

  In addition, the power source 36 of the information display device 100 is provided with a power storage unit 37. As the power storage unit 37, a large amount of current can flow, so that the charging time is short, and no chemical reaction is involved. An electric double layer capacitor (EDLC), which is a power storage element in which almost no generation occurs, is used. The electric double layer capacitor used here is preferably a thin sheet type and flexible in consideration of ease of handling. However, flexibility is not a requirement. Then, such an electric double layer capacitor such as a thin sheet type is installed so as to occupy all or part of the inside and the back surface of the sheet-like information display device 100, for example. In addition, a small electric double layer capacitor such as a coin type or a wound type may be installed at an arbitrary position of the information display device 100.

  Next, the display 42 of the information display unit 40 requires electric power only during display rewriting, can hold information in a non-powered state, and uses electronic paper which is a sheet-like nonvolatile electronic display element. However, a display element other than electronic paper may be used as long as it is a sheet that requires only a small amount of power equivalent to that of electronic paper for driving. The display of information on the display 42 is controlled by a control circuit constituting the display control unit 41.

  The display operation unit 43 of the information display unit 40 operates display information such as display ON / OFF, content selection, page feed and jump, brightness / saturation / contrast adjustment, data transmission / reception operation, display enlargement / reduction, and the like. Can be input, and input is performed by a switch method, a touch input method, a jog dial method, or the like. Moreover, the system input by the touchscreen sensor on a display may be sufficient.

  On the other hand, in the charging device 200, the storage unit 54 of the data communication / power supply unit 50 is configured by a rewritable nonvolatile memory, and transmits / receives data to / from the external device, the communication network, and the information display device 100. save. Connection interfaces represented by LAN, WAN, and USB are used for connection to external storage devices typified by memory sticks and hard disks, external devices such as PCs, and communication networks.

  The antenna 55 of the charging device 200 is a loop antenna and may be an air core, like the antenna 35 of the information display device 100, but a magnetic material such as ferrite may be disposed inside. Similarly, the material of the antenna can improve the magnetic characteristics by using a metal or organic material having a low resistivity.

  In the power supply 56 of the charging device 200, the power supply unit 57 is configured by at least one of an AC / DC converter, a DC / DC converter, a primary battery / secondary battery, a capacitor, a solar battery, and a fuel battery. In addition, the charging device 200 can be used by removing the power from the USB terminal when connected to a personal computer or the like. Thus, when there is a commercial AC power source, an AC / DC converter is used as a power source, and when there is no commercial AC power source, a DC / DC converter, a primary battery, a secondary battery, a capacitor, a solar cell, or a fuel cell. At least one power source is used as a power source.

  A display 61 provided in the operation unit 60 of the charging device 200 is configured by a liquid crystal, an LED, an organic EL, and the like, and displays information such as a charging state of each information display device 100, a data transmission / reception state, and an error. The operation device 62 provided in the operation unit 60 is configured to be able to perform operations such as charging / data transmission start / stop, transmission data selection, communication with an external device, mode selection, switch method, touch input method, Input using the jog dial method.

  FIG. 2 shows a state where a plurality of information display devices 100 are installed in the charging device 200. (A) is an example in which the information display device 100 is installed in a flat state, and (B) is an example in which the information display device 100 is installed in a vertical state. Note that the sheet-like information display device 100 used in these examples may be flexible either in its entirety or in part, or may be inflexible that does not bend.

  In the example shown in FIG. 2A, a large display device installation unit 80 is provided on the surface of the charging device 200 formed in a flat plate shape, and an operation unit 60 is provided in front of the display device installation unit 80, so Set up side by side. Then, a sheet-shaped information display device 100 that is convenient to carry is loaded on the display device installation unit 80, and a plurality of information display devices 100 are crossed with the power supply magnetic flux and the data communication magnetic flux generated by the charging device 200. Install them in layers. A large display 42 is provided on the surface of the information display device 100, and a display operation unit 43 is provided in front of the display 42.

  In the example shown in FIG. 2B, the charging device 200 formed in a block shape is provided with an upward concave portion, and the concave portion serves as a display device installation portion 80, and an operation unit 60 is provided on one side of the display device installation portion 80. The display 61 and the operation device 62 are provided side by side. Then, with the sheet-shaped information display device 100 standing up, the information is overlapped in the front-rear direction and the lower part is inserted into the display device installation unit 80 to cross the power supply magnetic flux and the data communication magnetic flux generated by the charging device 200. A plurality of display devices 100 are stacked and installed. A large display 42 is provided on the surface of the information display device 100, and a display operation unit is provided at a position hidden below the charging device 200 in the drawing.

  Thereby, charging and data transmission / reception can be simultaneously performed in a non-contact manner by electromagnetic induction in a plurality of information display devices 100 at once.

First, charging to the power source 36 of the information display device 100 will be described.
First, before starting charging, the charging device 200 receives a response signal including the communication ID from the information display device 100 to be charged. Then, the number of information display devices 100 is detected, and charging is started with power suitable for the number. Thereafter, charging is continued while controlling the state of the magnetic circuit to an optimum state.

  Charging is terminated by stopping the charging magnetic field when full charge of the power source 36 of the information display device 100 is detected by monitoring the voltage value or when a predetermined time has elapsed by the timer. When charging is completed, a charging completion signal is transmitted from the information display device 100 side, and charging completion is displayed on the display 61 of the charging device 200. At this time, the completion of charging may be displayed on the information display device 100 side or on both the information display device 100 and the charging device 200.

  If the data transmission / reception is not completed when the charging completion signal is received, the transmission of the charging magnetic field is continued and stopped when the data transmission / reception is completed. When one or several of them are inserted / removed during charging of the plurality of information display devices 100, the magnetic field comparison unit 58 detects a change in the magnetic circuit so that the circuit system can continue to be charged efficiently. Adjust to the state and control the magnetic flux of electromagnetic induction.

Next, data transmission / reception between the information display device 100 and the charging device 200 will be described.
When data is transmitted collectively to a plurality of information display devices 100, the charging device 200 first receives a response signal including a communication ID, and detects the number of information display devices 100. Then, the magnetic circuit state is controlled to an optimum state, and data is transmitted to each information display device 100 at once.

  When some information display devices 100 are pulled out on the way, the number of information display devices 100 is detected by a response signal received by the charging device 200 or a change in the magnetic circuit is detected. The circuit state is optimally controlled and data transmission is continued. At this time, a display indicating that the data is incomplete may be displayed on the extracted information display device 100. On the other hand, when some information display devices 100 are inserted on the way, the number of information display devices 100 and the data reception status of each information display device 100 are detected by analyzing the response signal including the communication ID, and the magnetic The circuit state is optimally controlled and data corresponding to the data reception status of each information display device 100 is transmitted.

  When data is selectively transmitted to a plurality of information display devices 100, the charging device 200 receives a response signal including a communication ID from the target information display device 100, the number of information display devices 100, The data reception status of the information display device 100 is detected. And while controlling a magnetic circuit state optimally, the data according to the data reception condition of each information display apparatus 100 are transmitted. Further, when the information display device 100 is inserted / removed during data transmission, the optimum control of the magnetic circuit state is performed, and the information display device 100 inserted / removed from the communication ID is detected. Data transmission to the device 100 is newly started, and in the case of extraction, data transmission to the information display device 100 is stopped.

  FIG. 3 shows an example of charging and data transmission between the plurality of information display devices 100 having ID1 to IDn as communication IDs and the charging device 200. In this example, for simplification of description, a case where each control is performed by one control unit will be described.

  When the information display device 100 is detected (1), the presence or absence of transmission data to the information display device 100 stored in the storage unit 54 of the charging device 200 is confirmed (2), the timer is turned on (3), and charging is performed. A magnetic field is sent out (4). At this time, the charging magnetic field from the charging device 200 side is repeatedly transmitted ON / OFF repeatedly. In addition, a response signal (10) including an ID code, a charging status, and a data reception status is periodically transmitted from each information display device 100 to the charging device 200 when the charging magnetic field is turned off.

  If there is transmission data in (2), while reading the data in the storage element of the storage unit 54 (5), the ID code is added to the data as a header, and then sequentially superimposed on the charging magnetic field and transmitted ( 6). By receiving each of these data by the information display device 100 corresponding to the ID, different data can be selectively sent out for each information display device 100. Further, the same information is transmitted to each information display device 100 by sending the same data having no header or having a plurality of ID codes in the header.

  In the external interface unit 70, data can be exchanged by communication with an external device (such as a PC), and can be stored / read in the storage element of the storage unit 54. Further, by connecting to an external communication network (LAN, WAN), information can be taken in from the external communication network or transmitted to the external communication network.

  The information display device 100 receives the charging magnetic field (4) and charges the electric double layer capacitor (EDLC) constituting the power storage unit 37 (7). When the charging voltage of the electric double layer capacitor is monitored and charging completion is confirmed (8), a self-ID is attached to the charging device 200 during the charging magnetic field OFF timing, and a charging completion signal is returned (10). When it is confirmed that the electric double layer capacitor is fully charged, the information display device 100 performs control so that the electric double layer capacitor is not overcharged. In addition, only the data with its own ID is extracted from the data sent from the charging device 200 and stored in the storage element of the storage unit 34 of the information display device 100 (9).

  Data such as the charging status and data reception status of the information display device 100 is displayed on the display 61 in the charging device 200 as a status. Similarly, the information display device 100 may display a status on the display 42 according to the operation state during charging.

  When the charging device 200 receives charging completion signals from all the information display devices 100 (10), or when the set timer is turned off (3), the charging device 200 displays the charging completion status on the display 61, While notifying the user of the state, the charging magnetic field is turned off.

  When the charging completion signal from the information display device 100 is detected (10), or even when the set timer is turned off, the charging magnetic field is not turned off if the transmission data is not finished for an arbitrary ID. This is continued until the data communication is completed.

  When an arbitrary information display device 100 is pulled out during charging, a change in state between the primary side and the secondary side of the magnetic circuit due to a change in state of the charging magnetic field system is detected, and the magnetic circuit is controlled to an optimum state. Then, the information display device 100 extracted by analysis of the response signal is specified, and data transmission to the information display device 100 is stopped. However, when the same data is sent all at once, the data transmission stop operation is not necessary. Further, when the information display device 100 is newly inserted during charging, a change in the magnetic circuit state is detected in the same manner as withdrawing, the magnetic circuit state is optimally controlled, and the added information display device 100 The response signal is analyzed, and transmission of data corresponding to the ID is started.

  FIG. 4 shows a configuration example of an electric double layer capacitor used as the power storage unit 37 in the power source 36 of the information display device 100.

  As shown in the figure, in the electric double layer capacitor, one electrode for an electric double layer capacitor is a positive electrode body 103 composed of a current collector 101 and an active material layer 102 for exchanging electricity with the outside. Two electric double layer capacitor electrodes are used as a negative electrode body 104 that is similarly composed of a current collector 101 and an active material layer 102. In order to prevent contact between the positive electrode body 103 and the negative electrode body 104, a separator 105 is provided between them, and the positive electrode body 103, the negative electrode body 104, and the separator 105 are impregnated with an electrolytic solution and sealed in the case 106. Configured.

  As a result, uneven patterns are formed on both the front and back surfaces of the active material forming material, so that the internal resistance of the active material layer itself is low, the electrical connection between the active material layer and the current collector is good, and high output characteristics It is possible to obtain an electric double layer capacitor having

  FIG. 5 shows an example of a method for manufacturing an electrode for an electric double layer capacitor used as the positive electrode body 103 or the negative electrode body 104 constituting the electric double layer capacitor. In the manufacturing method shown in FIG. 5, the scale of each component is not considered in order to make the contents of the invention easy to understand.

  First, in FIG. 5, a lower mold 2 and an upper mold 3 are prepared as shown in FIG. The lower mold 2 and the upper mold 3 use materials such as metal, ceramics, and glass, and use known mold processing techniques such as a photolithography technique, an X-ray lithography technique, an etching technique, an electroforming technique, and a machining technique. Alternatively, these mold processing techniques are used in combination. In the illustrated example, a nickel-based alloy made by electroforming a Si master mold processed using a photolithography technique and an etching technique is used.

  The lower mold 2 and the upper mold 3 are respectively provided with irregular patterns 4 and 5 having an arbitrary size and an arbitrary shape at arbitrary positions. In this example, the upper surface of the convex portion is 0.5 μm square, the base is 1 μm square, the height is 0.5 μm, and many patterns having tapered side surfaces are formed. And the lower mold | type 2 and the upper mold | type 3 are arrange | positioned so that the uneven | corrugated pattern 4 and 5 formed mutually may be opposed.

  Next, as shown in (B), the active material forming material 1 is supplied between the lower mold 2 and the upper mold 3. The active material forming material 1 only needs to contain at least an electrode active material and a binder, and here, it is composed of an electrode active material, a binder, and a conductive auxiliary material, and the electrode active material is granular activated carbon particles, and the binder is Although carbon black is used as the fluorine-based polymer and the conductive auxiliary material and these materials are kneaded, it is not particularly limited to such materials.

  Then, as shown in (C), the active material forming material 1 is pressed by the lower mold 2 and the upper mold 3 to be dried while being filled in the concavo-convex patterns 4 and 5. As other methods for filling the concavo-convex patterns 4 and 5 with the active material forming material 1, there are other methods such as a coating method by spin coating or spraying, a dipping method, a doctor blade method, a rolling method using a roller or the like. .

  That is, in this example, the lower mold 2 and the upper mold 3 are arranged so that the concave and convex patterns 4 and 5 formed on the lower mold 2 and the upper mold 3 face each other. An active material 1 containing at least an electrode active material and a binder is supplied between the lower die 2 and the upper die 3 by using a pressing mechanism (not shown). Is to be pressurized.

  Thereafter, as shown in (D), when the lower mold 2 and the upper mold 3 are peeled from the active material forming material 1, the concave and convex patterns 9 and 8 having an arbitrary size on the front and back surfaces are formed. The power storage device active material 6 to be formed is manufactured. The surface on which the concave / convex pattern 4 of the lower mold 2 is formed and the surface on which the concave / convex pattern 5 of the upper mold 3 is formed are each subjected to surface treatment so that the active material forming material 1 can be easily peeled off. Good.

  Next, as shown in (E), the current collector 7 is fixed to one side of the power storage device active material 6 as an active material layer, and the electric double layer capacitor electrode 10 is manufactured.

  FIG. 6 shows another method for manufacturing the electrode for the electric double layer capacitor. Similarly, in the manufacturing method shown in FIG. 6, the scale of each component is not taken into consideration in order to make the contents of the invention easy to understand.

  First, also in FIG. 6, as shown to (A), the lower mold | type 12 and the upper mold | type 13 are prepared. The lower mold 12 and the upper mold 13 are made of the same material as that used in the manufacturing method shown in FIG. In the illustrated example, similarly, a nickel-based alloy manufactured by electroforming a Si master mold processed using a photolithography technique and an etching technique is used.

  Similarly, the lower mold 12 and the upper mold 13 are respectively provided with irregular patterns 14 and 15 having an arbitrary size and an arbitrary shape at an arbitrary position. In this example, the upper surface of the convex portion is 0.5 μm. A large number of patterns having a tapered side surface with a corner having a base of 1 μm square and a height of 0.5 μm are formed. And the lower mold | type 12 and the upper mold | type 13 are arrange | positioned facing the uneven | corrugated patterns 14 and 15 mutually formed.

  Then, as shown in (B), the active material forming material 11 is filled into the concave / convex pattern 14 formed on the lower mold 12 by, for example, a spin coating method. The active material forming material 11 only needs to contain at least an electrode active material and a binder. Here, granular activated carbon particles are used as an electrode active material, a fluorine-based polymer is used as a binder, and carbon black is used as a conductive auxiliary material. Dispersed in solution is used.

  Next, as shown in (C), the upper mold 13 pushes against the active material forming material 11 on the lower mold 12 until the active material forming material 11 enters the concave portion of the concave / convex pattern 15 formed on the upper mold 13. It is dried while being applied.

  Thereafter, as shown in (D), when the lower mold 12 and the upper mold 13 are peeled from the active material forming material 11, the concave and convex patterns 19 and 18 having an arbitrary size on the front and back surfaces are formed. The power storage device active material 16 to be formed is manufactured. In this example, in order to increase the density of the active material 16 for the electricity storage device, a compressive load is applied to the active material forming material 11 when the active material forming material 11 is dried. Also in this case, the surface treatment is performed on the surface on which the concave / convex pattern 14 of the lower mold 12 and the surface on which the concave / convex pattern 15 of the upper mold 13 are formed so that the active material forming material 11 can be easily peeled off. It is good to give.

  Next, as shown in (E), the current collector 17 is fixed to one surface of the power storage device active material 16 as an active material layer, and the electric double layer capacitor electrode 20 is manufactured.

  FIG. 7 shows still another example of the method for manufacturing the electrode for the electric double layer capacitor. Similarly, in the manufacturing method shown in FIG. 7, the scale of each component is not taken into consideration in order to make the contents of the invention easy to understand.

  First, in the manufacturing method shown in FIG. 7, as shown to (A), the metal mold | die 22 is prepared. The mold 22 uses a material such as metal, ceramics, and glass, and uses a known mold processing technique such as a photolithography technique, an X-ray lithography technique, an etching technique, an electroforming technique, a machining technique, or the like. Made using a combination of processing techniques. In the illustrated example, a nickel-based alloy made by electroforming a Si master mold processed using a photolithography technique and an etching technique is used.

  An uneven pattern 23 having an arbitrary size and an arbitrary shape is formed on the mold 22 at an arbitrary position. In this example, the upper surface of the convex portion is 0.5 μm square, the base is 1 μm square, the height is 0.5 μm, and many patterns having tapered side surfaces are formed.

  Next, as shown in (B), the active material forming material 21 is supplied to the concavo-convex pattern 23 formed on the mold 22. The active material forming material 21 only needs to contain at least an electrode active material and a binder. Here, the active material forming material 21 includes an electrode active material, a binder, and a conductive auxiliary material. As the electrode active material, granular activated carbon particles, and as a binder, Although carbon black is used as the fluorine-based polymer and the conductive auxiliary material and these materials are kneaded, it is not particularly limited to such materials.

  Then, as shown in (C), the active material forming material 21 may be directly pressed by a pressing member 25 made of a press head, a pressing plate, or the like, but here the adhesive member 27 is placed on the active material forming material 21. A current collector 26 is placed via And as shown to (D), when the electrical power collector 26 is pressurized by the pressurization member 25, it dries, filling the recessed part of the uneven | corrugated pattern 23 with the active material formation material 21, and the active material formation material A current collector 26 is fixed to 21.

  As a method for filling the concavo-convex pattern 23 with the active material forming material 1, there are a method of applying by spin coating or spraying, a method of dipping, a doctor blade method, a method of rolling with a roller or the like in addition to pressurization.

  In the illustrated example, an adhesive member 27 having conductivity is used to make the active material forming material 21 and the current collector 26 more firmly fixed, but the adhesive member 27 has conductivity. It is not limited to.

  Thereafter, as shown in (E), the pressure member 25 is removed, and the mold 22 is peeled from the active material forming material 21, whereby the current collector 26 is formed on the active material layer 24 made of the active material forming material 21. The electrode 29 for an electric double layer capacitor to which is fixed is manufactured. An uneven pattern 28 having an arbitrary size and an arbitrary shape is formed on one surface of the active material layer 24 formed of the active material forming material 21. The surface of the mold 22 on which the concave / convex pattern 23 is formed is preferably subjected to surface treatment so that the active material forming material 21 can be easily peeled off.

  Here, since the draft side is provided with the convex side surface of the concavo-convex pattern 23 as a tapered side surface, and the die 22 is peeled off from the active material forming material 21 by the draft, the die from the active material forming material 21 is provided. 22 can be easily peeled off, and the productivity can be improved by using a molding technique excellent in releasability, and the production of an electrode for an electric double layer capacitor can be simplified.

  As described above, the first step (step shown in FIGS. 7A and 7B) in which the active material forming material 21 is supplied to the uneven pattern 23 formed in the mold 22, and the active material forming material 21 In the second step (steps shown in FIGS. 7C and 7D) where the current collector 26 is fixed, and in the third step (FIG. 7E) where the mold 22 is peeled from the active material forming material 21. Therefore, the size of the active material layer 24 formed of the active material forming material 21 by using a molding technique having excellent releasability can be arbitrarily fine and has a size of μm and sub-μm. By forming the concavo-convex pattern 23 having the shape with good reproducibility, it is possible to manufacture an electrode for an electric double layer capacitor having low internal resistance of the active material layer 24 itself and high output characteristics.

  In addition, since the current collector 26 is fixed to the active material forming material 21 by being pressurized in the second step, the density of the active material layer formed by the active material forming material 21 is increased, and at the same time, the active material The adhesion between the layer and the current collector 26 is made stronger, the current collector 26 is easily adhered to the active material layer, the productivity is improved, the production of the electrode for the electric double layer capacitor is simplified, and further Reduction of internal resistance can be realized.

  Furthermore, in the second step, the current collector 26 is fixed to the active material forming material 21 while being filled with the active material forming material 21 in the recesses of the concavo-convex pattern 23 by being pressurized. The concave / convex pattern 23 on the surface of the concave / convex pattern 23 formed on the mold 22 can be formed together with the active material forming material 21 and the current collector 26. The filling of the active material forming material 21 can be performed to easily fill the uneven pattern 23 with the active material forming material 21, thereby improving the productivity and simplifying the production of the electrode for the electric double layer capacitor.

DESCRIPTION OF SYMBOLS 1 Active material formation material 2 Lower mold | type 3 Upper mold | type 4 Lower mold | type uneven | corrugated pattern 5 Upper mold | die uneven | corrugated pattern 6 Active material for electrical storage devices 7 Current collector 8 Uneven pattern of the back surface of the active material for electrical storage devices 9 Active material for electrical storage devices Surface irregularity pattern 10 Electrode for electric double layer capacitor 11 Active material forming material 12 Lower mold 13 Upper mold 14 Lower mold uneven pattern 15 Upper mold uneven pattern 16 Current storage device active material 17 Current collector 18 Power storage device active Uneven pattern on the back surface of the material 19 Uneven pattern on the surface of the active material for the electricity storage device 20 Electrode for electric double layer capacitor 21 Active material forming material 22 Mold 23 Uneven pattern of the mold 24 Active material layer 25 Pressure member 26 Current collector 27 Adhesive member 28 Concavity and convexity pattern of active material layer 29 Electrode for electric double layer capacitor 30 Data communication / control unit 31 Data transmission Reception control unit 32 Charging / discharging control unit 37 Power storage unit 40 Information display unit 50 Data communication / power supply unit 51 Data transmission / reception control unit 52 Power supply control unit 57 Power supply unit 58 Magnetic field comparison unit 60 Operation unit 80 Display device installation unit 100 Information display Device 200 Charging device

Claims (10)

A portable information display device comprising an information display unit for displaying information, a data transmission / reception control unit, a charge / discharge control unit, and a data communication / control unit having a power storage unit;
A data transmission / reception control unit for controlling transmission / reception of data to / from the information display device, a data communication / power supply unit having a power supply control unit for controlling power supply to the information display device, a power supply unit, and an operation unit. A charging device that transmits and receives data simultaneously with charging by electromagnetic induction with respect to the information display device;
An information display system device comprising:   The information display system apparatus according to claim 1, wherein a nonvolatile electronic display element is used for the information display unit.   The information display system apparatus according to claim 1, wherein an electric double layer capacitor is used for a power storage unit included in the data communication / control unit.   An active material forming material containing at least an electrode active material and a binder is supplied between a lower mold and an upper mold in which the concavo-convex patterns formed to face each other, and the active material forming material is the lower mold After pressing the mold and the upper mold, the lower mold and the upper mold are peeled to produce an active material for an electricity storage device, and the active material for an electricity storage device is collected on one side as an active material layer. 4. The information display system apparatus according to claim 3, wherein an electric body is fixed to produce an electrode for an electricity storage device, and the electric double layer capacitor is formed using the electrode for the electricity storage device.   An active material forming material containing at least an electrode active material and a binder is supplied to the concavo-convex pattern formed on the lower mold, and the upper mold until the active material forming material enters the concavo-convex pattern formed on the upper mold. Is pressed against the active material forming material, and then the upper die and the lower die are peeled to produce an active material for an electricity storage device. The active material for an electricity storage device is collected on one side as an active material layer. 4. The information display system apparatus according to claim 3, wherein an electric body is fixed to produce an electrode for an electricity storage device, and the electric double layer capacitor is formed using the electrode for the electricity storage device.   A first step in which an active material forming material containing at least an electrode active material and a binder is supplied to the uneven pattern formed in the mold, and a second step in which a current collector is fixed to the active material forming material. And a third step in which the mold is peeled off from the active material forming material, and an electric storage device electrode is formed, and the electric double layer capacitor is formed using the electric storage device electrode. The information display system apparatus according to claim 3.   The display device installation section for installing a plurality of the information display devices is provided in the charging device so as to cross the power supply magnetic flux and the data communication magnetic flux generated by the charging device. The information display system apparatus according to any one of the above.   The information display system apparatus according to claim 7, wherein the information display device is formed in a sheet shape.   The information display system apparatus according to claim 7, wherein the charging device includes a magnetic field comparison unit that detects insertion / removal of the information display device.   The information display system apparatus according to claim 1, wherein each of the information display devices has a communication ID.

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