JP2007072285A - Liquid crystal display device and inspecting device for liquid crystal cell - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid crystal display device that can input corresponding signals to a plurality of kinds of liquid crystal cells while using components in common, and an inspecting device for a liquid crystal cell. <P>SOLUTION: The liquid crystal display device is equipped with a relay conversion substrate 6 which is connected to a signal output circuit and a liquid crystal cell and receives an output signal of the signal output circuit to output it to the liquid crystal cell, and the substrate 6 is provided with a relay wiring pattern 8a which outputs the output signal with the number of lines corresponding to liquid crystal cells A, a conversion wiring pattern 8b which outputs the output signal with the number of lines corresponding to liquid crystal cells B different in kind from the liquid crystal cells A, connector FFCs 71ax, 72ax, 7ay, 71bx, 72bx, and 7by which switch the flow passages of the output signal to one of the wiring patterns 8a and 8b by engagement of FFCs 51ax, 52ax, 6ay, 51bx, 52bx, and 5by, and a voltage switching circuit 9 which switches the voltage level of the output signal to a level corresponding to the liquid crystal cell A or liquid crystal cell B by turning ON/OFF a switch S. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a liquid crystal display device using a liquid crystal cell and a liquid crystal cell inspection device for inspecting the operation of the liquid crystal cell.

  Liquid crystal cells (also called liquid crystal panels) are purchased from other companies for manufacturers of liquid crystal modules and liquid crystal display devices such as liquid crystal televisions that incorporate them, and electronic components such as drivers and microcomputers are connected to the liquid crystal cells. There are places where it has become a device by doing. In order to reduce costs, the liquid crystal display manufacturer switches the liquid crystal cell purchaser to a manufacturer that provides liquid crystal cells at a lower price, or increases and secures the number of supplies to the market (that is, mass production). In some cases, liquid crystal cells are purchased from multiple manufacturers.

  However, in general, the types (specifications) of liquid crystal cells are different for each manufacturer and the number of input lines for signals for displaying images, voltage levels, and the like are different. For this reason, when a manufacturer of a conventional liquid crystal display device uses a plurality of types of liquid crystal cells, a signal output circuit that outputs a voltage level signal corresponding to each liquid crystal cell is provided. Designed for each type, it was necessary to manufacture a dedicated substrate on which each of the signal output circuits was formed. As described above, manufacturing a dedicated substrate having a signal output circuit for each type of liquid crystal cell has been an obstacle to reducing the cost of the liquid crystal display device because the components cannot be shared. Also, in the inspection process for checking the operation of the liquid crystal cell by inputting the signal output from the signal output circuit to the liquid crystal cell, a signal output circuit for outputting a signal corresponding to the liquid crystal cell every time the type of the liquid crystal cell changes The special substrate on which the substrate is formed must be used, and it takes time and effort to replace the special substrate, which has been an obstacle to improving work efficiency.

On the other hand, Patent Document 1 below discloses a liquid crystal panel inspection apparatus that branches a signal output from a signal generator into a number of lines corresponding to the liquid crystal panel by a relay substrate and a probe and inputs the branched signal to the liquid crystal panel. Yes. Further, in Patent Document 2 below, odd-numbered and even-numbered corresponding connectors are mounted on the surface of the relay board, and odd-numbered and even-numbered corresponding lands are formed to contact the tester probe. And wiring patterns that connect the two lands to each other, and through holes that connect the wiring patterns on the front and back surfaces are provided, and the flexible substrate connected to the liquid crystal panel is divided into odd and even patterns, and each connection end A liquid crystal panel inspection apparatus is disclosed in which an output signal from a tester is input to a liquid crystal panel by connecting the connector to odd and even connectors. Further, in Patent Document 3 below, an output signal of a driver IC of a liquid crystal panel is connected to a connector via a connection board and a cable and relayed by a jumper wiring, a connection component, and a reinforcing board, An inspection apparatus for a liquid crystal panel that inputs to a contact is disclosed. Further, in Patent Document 4 below, a switching unit for a linear motor including a relay board that changes the number of signal lines so that signals input from three input side connectors can be output from two output side connectors ( A switch box).
JP 2002-107688 A Japanese Patent Application Laid-Open No. 2004-325962 JP-A-5-232419 JP 2004-215359 A

  However, in the substrates, probes, connectors and the like disclosed in Patent Documents 1 to 4, the output signal from the signal output circuit is changed to the number of lines corresponding to one type of liquid crystal cell and input to the liquid crystal cell. However, the number of lines and the voltage level corresponding to each of a plurality of types of liquid crystal cells cannot be changed and input to each liquid crystal cell. Therefore, when multiple types of liquid crystal cells are used, a dedicated signal output circuit that outputs a corresponding signal for each type of liquid crystal cell and a dedicated relay board with corresponding wiring etc. are manufactured and used. As described above, this is an obstacle to cost reduction of the liquid crystal display device and improvement of work efficiency in the liquid crystal cell inspection process.

  The present invention solves the above-described problems, and the problem is that a liquid crystal display device that can input signals corresponding to a plurality of types of liquid crystal cells while sharing parts, and An object of the present invention is to provide a liquid crystal cell inspection apparatus.

  In the present invention, in a liquid crystal display device that inputs a signal output from a signal output circuit to a liquid crystal cell and operates the liquid crystal cell to display an image or a liquid crystal cell inspection device that inspects the operation of the liquid crystal cell, A relay conversion member connected to the output circuit and the liquid crystal cell and receiving an output signal from the signal output circuit and outputting the output signal to the liquid crystal cell; the relay conversion member having the line corresponding to the first liquid crystal cell; A first wiring that outputs in number, a second wiring that outputs the output signal in the number of lines corresponding to a second liquid crystal cell of a different type from the first liquid crystal cell, and a distribution path of the output signal Wiring switching means for switching to the first wiring or the second wiring, and voltage switching means for switching the voltage level of the output signal to a level corresponding to the first liquid crystal cell or a level corresponding to the second liquid crystal cell are provided. That.

  As described above, when the output signal from the signal output circuit is received by the relay conversion member and output to the liquid crystal cell, when the liquid crystal cell is the first liquid crystal cell, the distribution path of the output signal is changed by the wiring switching means. In the case where the voltage level of the output signal is set to a level corresponding to the first liquid crystal cell by the voltage switching means and the liquid crystal cell is the second liquid crystal cell, the wiring switching means distributes the output signal. By setting the path to the second wiring and setting the voltage level of the output signal to a level corresponding to the second liquid crystal cell by the voltage switching means, the output signal is changed between the first and second types of relay conversion members. A signal corresponding to the liquid crystal cell can be input to each liquid crystal cell. Therefore, a common signal output circuit and relay conversion member can be used for a plurality of types of liquid crystal cells, and signals corresponding to the respective liquid crystal cells can be input. As a result, it is no longer necessary for manufacturers of liquid crystal display devices to manufacture and use a signal output circuit and a relay conversion member for each type of liquid crystal cell, and by sharing these components, the cost of the liquid crystal display device and the inspection device can be reduced. In addition, it is not necessary to replace the signal output circuit and the relay conversion member for each type of liquid crystal cell in the liquid crystal cell inspection process, thereby improving work efficiency.

  Further, in the liquid crystal display device or the liquid crystal cell inspection device according to the present invention, the relay conversion member is formed of a multilayer substrate, and the first wiring and the second wiring are respectively arranged on different layers of the multilayer substrate. The wiring switching means and the voltage switching means are arranged on the surface layer of the multilayer substrate.

  As described above, by arranging the first wiring and the second wiring in different layers of the multilayer substrate of the relay conversion member, the arrangement space for the first and second wirings can be easily secured. The first and second wirings are not complicated, and the multilayer substrate can be reduced in size. Further, by arranging the wiring switching means and the voltage switching means on the surface layer of the multilayer substrate, the wiring switching means and the voltage switching means can be easily operated, and the thickness of the relay conversion member is reduced. It is possible to reduce the thickness of the liquid crystal display device and the inspection device.

  Furthermore, in an exemplary embodiment of the present invention, a signal output from a signal output circuit is input to a liquid crystal cell, and the operation of the liquid crystal display device or the liquid crystal cell that displays the image by operating the liquid crystal cell is inspected. In the liquid crystal cell inspection apparatus, the signal output circuit outputs a signal having a voltage level corresponding to the number of lines corresponding to the first liquid crystal cell, connected to the signal output circuit and the liquid crystal cell, and an output signal from the signal output circuit. And a relay conversion substrate composed of a multilayer substrate that outputs the output signal to the liquid crystal cell, the first wiring for relaying and outputting the output signal to the relay conversion substrate, and the type of the first liquid crystal cell. A second wiring for relaying and outputting while converting the number of lines corresponding to different second liquid crystal cells, wiring switching means for switching the output signal distribution path to the first wiring or the second wiring, The output signal Voltage switching means for switching whether the voltage level of the first liquid crystal cell is kept at a level corresponding to the first liquid crystal cell or converted to a level corresponding to the second liquid crystal cell is provided, and the second wiring, the wiring switching means, The voltage switching means is arranged on the surface layer of the relay conversion board, and the first wiring is arranged on a layer different from the surface layer of the relay conversion board.

  As described above, when the signal having the number of lines and the voltage level corresponding to the first liquid crystal cell output from the signal output circuit is received by the relay conversion substrate and output to the liquid crystal cell, the liquid crystal cell is the first liquid crystal cell. In some cases, the wiring switching means changes the output signal distribution path to the first wiring, and the voltage switching means causes the voltage level of the output signal to remain at the level corresponding to the first liquid crystal cell. In the case of the second liquid crystal cell, the distribution path of the output signal is changed to the second wiring by the wiring switching means, and the voltage level of the output signal is converted to a level corresponding to the second liquid crystal cell by the voltage switching means. Thus, the output signal can be input to each liquid crystal cell as a signal corresponding to the first and second liquid crystal cells of different types on the relay conversion board. Therefore, a common signal output circuit and relay conversion board can be used for a plurality of types of liquid crystal cells, and signals corresponding to the respective liquid crystal cells can be input. As a result, it is no longer necessary for the manufacturer of the liquid crystal display device to manufacture and use a signal output circuit and a relay conversion board for each type of liquid crystal cell, and these components are shared to reduce the cost of the liquid crystal display device and the inspection device. In addition, it is not necessary to replace the signal output circuit and the relay conversion board for each type of liquid crystal cell in the liquid crystal cell inspection process, thereby improving work efficiency. Also, by arranging the second wiring on the surface layer of the relay conversion board and the first wiring on a layer different from the surface layer, it is possible to easily secure the arrangement space for the first and second wirings. In addition, the first and second wirings are not complicated, and the substrate can be miniaturized. Furthermore, by arranging the wiring switching means and the voltage switching means on the surface layer of the relay conversion board, the wiring switching means and the voltage switching means can be easily operated, and the thickness of the relay conversion board in the component mounting state can be reduced. It is possible to reduce the thickness of the liquid crystal display device and the inspection device.

  According to the present invention, since the output signal from the signal output circuit is received by the relay conversion member and output to the liquid crystal cell, the wiring serving as the distribution path of the output signal is switched by the wiring switching means according to the type of the liquid crystal cell. By switching the voltage level of the output signal by the voltage switching means, the signal output circuit and the relay conversion member are made common to a plurality of types of liquid crystal cells, and signals corresponding to the respective liquid crystal cells are respectively input. Is possible.

  FIG. 1 is a diagram showing a configuration of a liquid crystal display device and a liquid crystal cell inspection device according to an embodiment of the present invention. The liquid crystal display device and the liquid crystal cell inspection device are manufactured and used by a liquid crystal display manufacturer (the liquid crystal display device is used by general users).

  The liquid crystal cells A and B are liquid crystal cells for liquid crystal televisions and the like that display a color image using a direct light type backlight as a light source. Since the liquid crystal cell A and the liquid crystal cell B are manufactured by different liquid crystal cell manufacturers, the types (specifications) are different, and the image and the wiring pattern formed on the glass substrates of the liquid crystal cells A and B are particularly different. The number of input lines, voltage level, and the like of signals input to display are different. The liquid crystal cell A constitutes an embodiment of the first liquid crystal cell in the present invention, and the liquid crystal cell B constitutes an embodiment of the second liquid crystal cell in the present invention.

  One end of COF (Chip On Film) 1ax, 1ay, 1ba, 1by is bonded to the right end and lower end on the glass substrate of each liquid crystal cell A, B by ACF (Anisotropic Conductive Film). On each COF 1ax, 1ay, 1bx, 1by, source drivers 2ax, 2bx and gate drivers 2ay, 2by, which are ICs for driving the liquid crystal cells A, B, are bonded by ACF, and each COF 1ax, 1ay, 1bx, 1by is attached. Are connected to the source relay boards 3ax and 3bx and the gate relay boards 3ay and 3by by soldering.

  Connectors 41ax, 42ax, 41bx, 42bx are mounted on the source relay boards 3ax, 3bx by soldering, and signals input from the connectors 41ax, 42ax, 41bx, 42bx are relayed to the COFs 1ax, 1bx. A wiring pattern to be formed is formed. On the COF 1ax and 1bx, a wiring pattern for relaying signals input from the source relay boards 3ax and 3bx to the source drivers 2ax and 2bx, and data signals (X that the source drivers 2ax and 2bx output based on the input signals) And a wiring pattern for supplying signals to the sources of TFTs (Thin Film Transistors) provided on the glass substrates of the liquid crystal cells A and B. On the gate relay boards 3ay and 3by, connectors 4ay and 4by are respectively mounted by soldering, and wiring patterns for relaying signals input from the connectors 4ay and 4by to the COFs 1ay and 1by are formed. . On the COF 1ay and 1by, a wiring pattern for relaying signals input from the gate relay boards 3ay and 3by to the gate drivers 2ay and 2by, and an address signal (Y that the gate drivers 2ay and 2by output based on the input signal) And a wiring pattern for supplying the signals to the gates of the TFTs provided on the glass substrates of the liquid crystal cells A and B.

  The relay conversion board 6 is a multilayer board, and connectors 71ax, 72ax, 71bx, 72bx, 7ay, 7by, 10m, and 10n are mounted on a surface layer 6f provided on the upper surface. One end of FFC (Flexible Flat Cable) 51ax, 52ax, 5ay is fitted to connectors 41ax, 42ax, 4ay, and the other end is fitted to connectors 71ax, 72ax, 7ay, respectively. A is electrically connected. On the other hand, one end of FFC 51bx, 52bx, 5by is fitted to connector 41bx, 42bx, 4by, and the other end is fitted to connector 71bx, 72bx, 7by, respectively, so that relay conversion substrate 6 and liquid crystal cell B are electrically connected. Connected. In each FFC 51ax, 52ax, 5ay, 51bx, 52bx, 5by, the data signals and address signals input from the connectors 71ax, 72ax, 7ay, 71bx, 72bx, 7by to be fitted to the connectors 41ax, 42ax, 4ay, 41bx, A wiring pattern for relaying to 42bx and 4by is formed.

  Connectors 12m and 12n are mounted on the signal output board 11, and a video signal input from an external device is processed to generate a signal having a number of lines corresponding to the liquid crystal cell A and a voltage level (liquid crystal cell A A signal output circuit 14 that outputs a data signal or an address signal capable of displaying an image by operating the A is formed. In the inspection process of the liquid crystal cells A and B at the liquid crystal display device manufacturer, a test video signal is input to the signal output circuit 14 from an external device such as a personal computer. When the user uses the liquid crystal display device, a video signal based on television broadcasting or the like is input to the signal output circuit 14 from an external device such as a tuner or a video.

  One end of the FFCs 13m and 13n shown between the relay conversion board 6 and the signal output board 11 is fitted to the connectors 10m and 10n, and the other end is fitted to the connectors 12m and 12n. The output board 11 is electrically connected. As described above, the relay conversion substrate 6 is connected to one of the liquid crystal cells A and B and connected to the signal output substrate 11, and receives the output signal from the signal output circuit 14 to receive the liquid crystal cells A and B. Output to. The relay conversion board 6 constitutes an embodiment of the relay conversion board and the relay conversion member in the present invention. The signal output circuit 14 constitutes an embodiment of the signal output circuit in the present invention.

  FIG. 2 is a view of the relay conversion board 6 as viewed from the right side of FIG. 6h shown by the broken line in the relay conversion board | substrate 6 is a through hole which electrically connects the surface layer 6f and the back surface layer 6u of this board | substrate 6, and the other intermediate | middle layer between these. On the back surface layer 6u of the relay conversion board 6, the signal output circuit 14 of the signal output board 11 is supplied to the liquid crystal cell A which is inputted through the connectors 12m, 12n, FFCs 13m, 13n, connectors 10m, 10n, and through holes 6h in order. A relay wiring pattern 8a for relaying and outputting a corresponding signal to the connectors 71ax, 72ax, 7ay is formed. Details of the relay wiring pattern 8a will be described later (FIG. 3). On the surface layer 6f of the relay conversion board 6, a signal corresponding to the liquid crystal cell A inputted from the signal output circuit 14 through the connectors 12m, 12n, FFCs 13m, 13n, and the connectors 10m, 10n sequentially is inputted to the liquid crystal cell B. A conversion wiring pattern 8b that relays and outputs to the connectors 71bx, 72bx, and 7by while converting to the corresponding number of lines is formed. Details of the conversion wiring pattern 8b will be described later (FIG. 4). The relay wiring pattern 8a constitutes an embodiment of the first wiring in the present invention, and the conversion wiring pattern 8b constitutes an embodiment of the second wiring in the present invention.

  Whether the distribution path of the output signal from the signal output circuit 14 in the relay conversion board 6 is the relay wiring pattern 8a of the back surface layer 6u or the conversion wiring pattern 8b of the front surface layer 6f is determined by the connectors 41ax, 42ax, 4ay. FFCs 51ax, 52ax, 5ay connected to the liquid crystal cell A via the connectors etc. are fitted into the connectors 71ax, 72ax, 7ay of the relay conversion board 6 or connected to the liquid crystal cell B via the connectors 41bx, 42bx, 4by, etc. The FFCs 51bx, 52bx, 5by thus made can be switched depending on whether they are fitted to the connectors 71bx, 72bx, 7by of the relay conversion board 6. The connectors 71ax, 72ax, 7ay, 71bx, 72bx, 7by constitute an embodiment of the wiring switching means in the present invention.

  In the middle of the conversion wiring pattern 8b of the surface layer 6f, the voltage level of the signal input from the signal output circuit 14 is left at a level corresponding to the liquid crystal cell A as described later, or corresponds to the liquid crystal cell B. A voltage switching circuit 9 for switching whether to convert the level is formed. Details of the voltage switching circuit 9 will be described later (FIG. 5). The voltage switching circuit 9 constitutes an embodiment of the voltage switching means in the present invention.

  FIG. 3 is a diagram showing the relay wiring pattern 8a on the back surface layer 6u of the relay conversion board 6 in a simplified manner. The ground pole GND of each connector 10m, 10n, 71ax, 72ax, 7ay is connected to the ground on the relay conversion board 6. Signals input from the signal output circuit 14 of the signal output board 11 to the connector 10m, for example, the polarity inversion signal POL, the drive voltage VDDD (+ 3.3V) of the driver 2ax, and the red signal OR input to the odd-numbered TFTs of the liquid crystal cell A The green signal OG, the blue signal OB, and the red signal ER input to the even-numbered TFTs are all relayed straight to the connector 71ax.

  A signal input from the signal output circuit 14 to the connector 10n is divided and relayed straight to the connector 72ax and the connector 7ay. For example, the green signal EG, the blue signal EB, the input voltage VDDA (+10.8 V) to the TFT source of the liquid crystal cell A, the gradation voltage VREF, and the like input to the even-numbered TFTs of the liquid crystal cell A are supplied to the connector 72ax. It is being relayed. Further, the drive voltage VDDD (+ 3.3V) of the driver 2ay, the OFF signal VEEG (−6V), the ON signal VDDG (+ 25V) and the like input to the TFT gate of the liquid crystal cell A are relayed to the connector 7ay.

  That is, from the above, the signals having the number of lines and the voltage level corresponding to the liquid crystal cell A input from the signal output circuit 14 to the connectors 10m and 10n are not converted by the relay wiring pattern 8a, but are directly connected to the connectors 71ax, 72ax, 7ay.

FIG. 4 is a diagram showing the conversion wiring pattern 8b of the surface layer 6f of the relay conversion board 6 in a simplified manner. The ground pole GND of each connector 10m, 10n, 71bx, 72bx, 7by is connected to the ground on the relay conversion board 6. Further, the color signal electrodes OE, OG, OB, ER, EG, and EB of the connectors 71bx and 72bx are also connected to the ground on the relay conversion board 6. A signal input from the signal output circuit 14 to the connector 10m is divided into a connector 71bx and a connector 72bx and relayed. For example, the polarity inversion signal POL, the drive voltage VDDD (+3.3 V) of the driver 2ax, and the red signal OR, the green signal OG, the blue signal OB, and the like input to the odd-numbered TFTs of the liquid crystal cell A are relayed to the connector 71bx. ing. The red signal ER input to the even-numbered TFTs of the liquid crystal cell A is relayed to the connector 72bx.

  A signal input from the signal output circuit 14 to the connector 10n is divided and relayed to the connector 72bx and the connector 7by. For example, the green signal EG, the blue signal EB, the input voltage VDDA (+10.8 V) to the TFT source of the liquid crystal cell A, the gradation voltage VREF, and the like input to the even-numbered TFTs of the liquid crystal cell A are supplied to the connector 72bx. It is being relayed. Among them, the input voltage VDDA (+ 10.8V) is converted into a voltage level (+ 13V) corresponding to the liquid crystal cell B by a voltage switching circuit 9 in the conversion wiring pattern 8b and then branched into three lines. And input to the corresponding pole of the connector 72bx.

  Further, the drive voltage VDDD (+ 3.3V) of the driver 2ay, the OFF signal VEEG (−6V), the ON signal VDDG (+ 25V), etc. input to the TFT gate of the liquid crystal cell A are branched into a plurality of lines, respectively. It is relayed to the corresponding 7-byte pole. Among them, the ON signal VDDG (+25 V) is converted into a voltage level (+24 V) corresponding to the liquid crystal cell B by the voltage reduction circuit 15 provided in the conversion wiring pattern 8 b, and then branched to two lines to be connected to the connector 7by. Is input to the corresponding pole. The voltage reduction circuit 15 is configured by a resistor or the like that can reduce the voltage level applied to the wiring pattern connecting the VDDG pole of the connector 10n provided with the circuit 15 and the VDDG pole of the connector 7by from + 25V to + 24V. This is a simple circuit (detailed illustration omitted).

  That is, from the above, the signal having the number of lines corresponding to the liquid crystal cell A and the voltage level input from the signal output circuit 14 to the connectors 10m and 10n has the number of lines corresponding to the liquid crystal cell B and the voltage level by the conversion wiring pattern 8b. Is input to the connectors 71bx, 72bx, and 7by.

  FIG. 5 is a diagram showing details of the voltage switching circuit 9 in the conversion wiring pattern 8b. The voltage switching circuit 9 includes a wiring pattern that has one connector 10n, 72bx side and branches into two in the middle, resistors R1, R2 of a predetermined size provided in the middle of the wiring pattern, and a switch S. It is configured. As shown in FIG. 2, the switch S is mounted on the relay conversion board 6 by soldering so as to be placed on the contacts C1 and C2 including the two pin terminals P1 and P2 and the pin terminals P1 and P2. The jumper terminal J is configured to be attached or removed to electrically connect or open the contacts C1 and C2.

  As shown in FIG. 5A, when the jumper terminal J of the switch S is removed from the pin terminals P1 and P2 and the contacts C1 and C2 are opened (the switch S is in the OFF state), a predetermined value is given from the connector 10n side. When a current value signal flows, the signal flows to the connector 72bx side through the resistor R1 and the resistor R2, as indicated by arrows. At this time, the combined resistance in the voltage switching circuit 9 is the sum of the resistors R1 and R2 (combined resistance = R1 + R2), and the voltage level of the signal flowing to the connector 72bx side is +10.8 V corresponding to the liquid crystal cell A.

  As shown in FIG. 5B, when the jumper terminal J is attached to the pin terminals P1 and P2 and the contacts C1 and C2 are connected (the switch S is in the ON state), a predetermined current is supplied from the connector 10n side. When the value signal flows, the signal branches after passing through the resistor R1, as indicated by the arrow, passes through the resistor R2, and passes through the contact C2 from the contact C1 through the jumper terminal J, and then merges again. It flows to the connector 72bx side. At this time, the combined resistance in the voltage switching circuit 9 is the sum of the product of the sum of the resistor R2 and the internal resistance of the switch S and the resistance R1 (where the internal resistance of the switch S is Rs, the combined resistance = (R2 × Rs) / (R2 + Rs) + R1), the voltage level of the signal flowing to the connector 72bx side is +13 V corresponding to the liquid crystal cell B.

  That is, the voltage level of the signal flowing to the connector 72bx side corresponds to the level corresponding to the liquid crystal cell A or the liquid crystal cell B by turning the switch S on or off by attaching / detaching the jumper terminal J to / from the pin terminals P1, P2. To the level you want.

  By assembling the above-described components as described above for the operation check inspection of the liquid crystal cells A and B at the manufacturer, an inspection apparatus for the liquid crystal cell A or the liquid crystal cell B is obtained. At that time, when the liquid crystal cell A is inspected, the connectors 41ax, 42ax, 4ay on the relay boards 3ax, 3ay and the connectors 71ax, 72ax, 7ay on the relay conversion board 6 shown in FIG. 1 are connected to the FFCs 51ax, 52ax, 5ay are respectively fitted, the liquid crystal cell A and the relay conversion board 6 are connected, and the switch S on the relay conversion board 6 shown in FIG. A signal having a number of lines and a voltage level corresponding to the liquid crystal cell A is input from the line 14 to the liquid crystal cell A via the relay conversion substrate 6, and the liquid crystal cell A operates based on the signal to be inspected. Further, when inspecting the liquid crystal cell B, the FFCs 51bx, 52bx, and 5by are fitted into the connectors 41bx, 42bx, and 4by on the relay boards 3bx and 3by and the connectors 71bx, 72bx, and 7by on the relay conversion board 6, respectively. When the liquid crystal cell B and the relay conversion board 6 are connected and the switch S on the relay conversion board 6 is turned on, the line corresponding to the liquid crystal cell B from the signal output circuit 14 through the relay conversion board 6 A signal having a numerical value and a voltage level is input, and the liquid crystal cell B operates based on the signal and can be inspected.

  On the other hand, by assembling the above-described parts as described above for the production of a liquid crystal display device, a liquid crystal display device (intermediate product) such as a liquid crystal module using the liquid crystal cell A or the liquid crystal cell B is obtained, and further, a frame or the like. By attaching other components, a liquid crystal display device (final product) such as a liquid crystal television is obtained. At that time, when the liquid crystal cell A is used, the FFC 51ax, 52ax, and 5ay are respectively fitted to the connectors 41ax, 42ax, and 4ay and the connectors 71ax, 72ax, and 7ay as described above, and the liquid crystal cell A and the relay conversion board are fitted. 6 and the switch S is turned off, a signal corresponding to the liquid crystal cell A is input from the signal output circuit 14 via the relay conversion substrate 6, and the liquid crystal cell A operates based on the signal. The image can be displayed. When the liquid crystal cell B is used, the FFCs 51bx, 52bx, and 5by are fitted into the connectors 41bx, 42bx, and 4by and the connectors 71bx, 72bx, and 7by, respectively, as described above, and the liquid crystal cell B and the relay conversion substrate 6 are fitted. And the switch S is turned on, a signal corresponding to the liquid crystal cell B is input from the signal output circuit 14 via the relay conversion substrate 6, and the liquid crystal cell B operates based on the signal. An image can be displayed.

  As described above, when the signal having the number of lines and the voltage level corresponding to the liquid crystal cell A output from the signal output circuit 14 is received by the relay conversion substrate 6 and output to the liquid crystal cells A and B, the liquid crystal cell A Depending on the type of B, the connectors 71ax, 72ax, 7ay, 71bx, 72bx, 7by on the relay conversion board 6 and the FFCs 51ax, 52ax, 5ay, 51bx, 52bx, 5by are connected to distribute the output signal. The path is switched to the relay wiring pattern 8a or the conversion wiring pattern 8b of the relay conversion board 6, and the switch S of the voltage switching circuit 9 on the relay conversion board 6 is turned OFF or ON, and the voltage level of the output signal is changed to the liquid crystal cell. By switching between the level corresponding to A or the level corresponding to the liquid crystal cell B, switching the output signal to the relay conversion board In the liquid crystal cell A in the signal corresponding to the liquid crystal cell A or the liquid crystal cell B, it is possible to input to the B. Therefore, the signal output circuit 14 and the relay conversion substrate 6 can be used in common for a plurality of types of liquid crystal cells A and B, and signals corresponding to the liquid crystal cells A and B can be input respectively. it can.

  As a result, it is not necessary for the liquid crystal display device manufacturer to manufacture and use the signal output circuit 14 and the relay conversion substrate 6 for each type of the liquid crystal cells A and B. By sharing these components, the liquid crystal display device and the liquid crystal cell can be used. The cost of the inspection apparatus can be further reduced. Further, in the inspection process of the liquid crystal cells A and B, it is not necessary to replace the signal output circuit 14 and the relay conversion substrate 6 for each type of the liquid crystal cells A and B, and it is possible to improve work efficiency.

  Further, by arranging the conversion wiring pattern 8b on the surface layer 6f of the relay conversion substrate 6 and the relay wiring pattern 8a on the back surface layer 6u different from the surface layer 6f, the space for arranging these wiring patterns 8a and 8b can be easily made. The wiring patterns 8a and 8b are not complicated, and the relay conversion board 6 can be downsized.

  Further, by arranging the connectors 71ax, 72ax, 7ay, 71bx, 72bx, 7by, 10m, 10n and the switch S of the voltage switching circuit 9 on the surface layer 6f of the relay conversion board 6, the connectors 71ax, 72ax, 7ay, 71bx, The FFC 51ax, 52ax, 5ay, 51bx, 52bx, 5by, 13m, and 13n can be easily fitted to 72bx, 7by, 10m, and 10n, and the jumper terminal J of the switch S can be easily attached and detached. Accordingly, the thickness of the liquid crystal display device and the liquid crystal cells A and B can be reduced.

  The present invention can adopt various forms other than the embodiment described above. For example, in the above embodiment, the case where the switch S including the pin terminals P1 and P2 and the jumper terminal J is provided in the voltage conversion circuit 9 is taken as an example, but the present invention is not limited to this. Absent. Instead of this, for example, a semiconductor switch or a tact switch may be provided. Further, for example, a circuit for setting the voltage level of the signal corresponding to the liquid crystal cell A is provided in the relay wiring pattern 8a, and a circuit for setting the voltage level of the signal corresponding to the liquid crystal cell B is provided in the conversion wiring pattern 8b. In addition, a circuit for changing the voltage level may be provided for each of the wiring patterns 8a and 8b. In this case, components such as the switch S are not necessary, and the connectors 71ax, 72ax, 7ay, 71bx, 72bx, and 7by on the relay conversion board 6 serve as the wiring switching means and voltage switching means. However, if the switch S that can be manually operated and visually check the operation state is provided on the surface layer 6f of the relay conversion substrate 6 as in the above-described embodiment, the operator who performs inspection and assembly can check whether the jumper terminal J is present. Further, the switching state of the voltage level can be recognized at a glance, and it is possible to prevent erroneous fitting of the FFCs 51ax, 52ax, 5ay, 51bx, 52bx, 5by to the connectors 71ax, 72ax, 7ay, 71bx, 72bx, 7by. That is, the voltage switching means of the present invention may be any means that can switch the voltage level of the signal input from the signal output circuit to a predetermined level.

  Moreover, in the above embodiment, the case where the conversion wiring pattern 8b and the relay wiring pattern 8a are respectively provided on the front surface layer 6f and the back surface layer 6u of the relay conversion substrate 6 is described as an example. It is not limited to. In addition to this, for example, one of the wiring patterns 8a and 8b may be provided on the surface layer 6f of the relay conversion substrate 6, and the other may be provided on an intermediate layer other than the surface layer 6f and the back surface layer 6u of the relay conversion substrate 6. Good. That is, wiring corresponding to different types of liquid crystal cells may be provided in different layers of the relay conversion substrate.

  In the above embodiment, the case where there are two types of liquid crystal cells to be used and inspected is taken as an example, but the present invention can also be applied to the case where there are three or more types of liquid crystal cells to be used and inspected. Is possible.

  Furthermore, in the above embodiment, the case where the present invention is applied to a liquid crystal display device using a liquid crystal cell for a liquid crystal television and an inspection device for the liquid crystal cell is given as an example. For example, the present invention can be applied to a liquid crystal display device using a small liquid crystal cell for a digital camera or a printer, and an inspection device for the liquid crystal cell.

It is a figure which shows the structure of the test | inspection apparatus of the liquid crystal display device which concerns on embodiment of this invention, and a liquid crystal cell. It is the figure which looked at the relay conversion board | substrate from the right side of FIG. It is a figure which shows the relay wiring pattern of a relay conversion board | substrate. It is a figure which shows the conversion wiring pattern of a relay conversion board | substrate. It is a figure which shows the voltage switching circuit in a conversion wiring pattern.

Explanation of symbols

6 relay conversion board 6f surface layer 6u back surface layer 71ax, 72ax, 7ay, 71bx, 72bx, 7by connector 8a relay wiring pattern 8b conversion wiring pattern 9 voltage switching circuit S switch 14 signal output circuit A, B liquid crystal cell

Claims (6)

In a liquid crystal display device that displays an image by inputting a signal output from a signal output circuit to a liquid crystal cell and operating the liquid crystal cell.
The signal output circuit outputs a voltage level signal with the number of lines corresponding to the first liquid crystal cell,
The relay conversion board comprising a multilayer board connected to the signal output circuit and the liquid crystal cell, receiving an output signal from the signal output circuit and outputting to the liquid crystal cell,
In the relay conversion board,
A first wiring for relaying and outputting the output signal;
A second wiring for relaying and outputting the output signal while converting the output signal into the number of lines corresponding to a second liquid crystal cell of a different type from the first liquid crystal cell;
Wiring switching means for switching the flow path of the output signal to the first wiring or the second wiring;
Voltage switching means for switching whether the voltage level of the output signal remains at a level corresponding to the first liquid crystal cell or converted to a level corresponding to the second liquid crystal cell;
The second wiring, the wiring switching means, and the voltage switching means are arranged in a surface layer of the relay conversion board, and the first wiring is arranged in a layer different from the surface layer of the relay conversion board. A liquid crystal display device. In the liquid crystal cell inspection apparatus for inputting the signal output from the signal output circuit to the liquid crystal cell and inspecting the operation of the liquid crystal cell,
The signal output circuit outputs a voltage level signal with the number of lines corresponding to the first liquid crystal cell,
The relay conversion board comprising a multilayer board connected to the signal output circuit and the liquid crystal cell, receiving an output signal from the signal output circuit and outputting to the liquid crystal cell,
In the relay conversion board,
A first wiring for relaying and outputting the output signal;
A second wiring for relaying and outputting the output signal while converting the output signal into the number of lines corresponding to a second liquid crystal cell of a different type from the first liquid crystal cell;
Wiring switching means for switching the flow path of the output signal to the first wiring or the second wiring;
Voltage switching means for switching whether the voltage level of the output signal remains at a level corresponding to the first liquid crystal cell or converted to a level corresponding to the second liquid crystal cell;
The second wiring, the wiring switching means, and the voltage switching means are arranged in a surface layer of the relay conversion board, and the first wiring is arranged in a layer different from the surface layer of the relay conversion board. Liquid crystal cell inspection device. In a liquid crystal display device that displays an image by inputting a signal output from a signal output circuit to a liquid crystal cell and operating the liquid crystal cell.
A relay conversion member connected to the signal output circuit and the liquid crystal cell, receiving an output signal from the signal output circuit and outputting to the liquid crystal cell;
In the relay conversion member,
A first wiring for outputting the output signal in the number of lines corresponding to the first liquid crystal cell;
A second wiring for outputting the output signal in the number of lines corresponding to a second liquid crystal cell of a different type from the first liquid crystal cell;
Wiring switching means for switching the flow path of the output signal to the first wiring or the second wiring;
A liquid crystal display device comprising: voltage switching means for switching a voltage level of the output signal to a level corresponding to the first liquid crystal cell or a level corresponding to the second liquid crystal cell. The liquid crystal display device according to claim 3.
The relay conversion member is composed of a multilayer substrate,
The first wiring and the second wiring are disposed in different layers of the multilayer substrate, respectively, and the wiring switching unit and the voltage switching unit are disposed on a surface layer of the multilayer substrate. Liquid crystal display device. In the liquid crystal cell inspection apparatus for inputting the signal output from the signal output circuit to the liquid crystal cell and inspecting the operation of the liquid crystal cell,
A relay conversion member connected to the signal output circuit and the liquid crystal cell, receiving an output signal from the signal output circuit and outputting to the liquid crystal cell;
In the relay conversion member,
A first wiring for outputting the output signal in the number of lines corresponding to the first liquid crystal cell;
A second wiring for outputting the output signal in the number of lines corresponding to a second liquid crystal cell of a different type from the first liquid crystal cell;
Wiring switching means for switching the flow path of the output signal to the first wiring or the second wiring;
An inspection apparatus for a liquid crystal cell, comprising: voltage switching means for switching a voltage level of the output signal to a level corresponding to the first liquid crystal cell or a level corresponding to the second liquid crystal cell. The liquid crystal cell inspection apparatus according to claim 5,
The relay conversion member is composed of a multilayer substrate,
The first wiring and the second wiring are disposed in different layers of the multilayer substrate, respectively, and the wiring switching unit and the voltage switching unit are disposed on a surface layer of the multilayer substrate. Liquid crystal cell inspection device.

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