Abstract:
A manufacturing method for a flat panel display module includes forming a display section having a transparent substrate with a wiring line terminal section adjacent at least one edge. A light emitting section is a center section, with a sealing cap covering the light emitting section. The sealing cap is dimensioned such that an edge of said sealing cap nearest the wiring line terminal section lies inside the wiring line terminal section. A flexible printed circuit board is provided with a semiconductor device mounted thereon. The flexible printed circuit board is connected to the wiring line terminal section of the transparent substrate, and a frame is fixed around the transparent substrate.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a flat panel display module and a manufacturing method, and more particularly to a flat panel display module which is made thin and small and a manufacturing method of the same. 
     2. Description of the Related Art 
     As a display unit used in an electronic unit like a mobile phone which is portable and small, flat panel display units such as an LCD and an organic EL display are known. Because the module of such a flat panel display unit is incorporated into the portable electronic equipment, the module is desired to be small and light. 
     Here, a conventional technique about the flat panel display module is disclosed in Japanese Laid Open Utility Model Application (JU-A-Heisei 1-161597). In this conventional technique, a flat panel display module is composed of a transparent substrate ( 1 ), a circuit board ( 18 ), many external lead connection terminal sections ( 23 ), and a the flexible lead ( 15 ). The transparent substrate ( 1 ) and the circuit board ( 18 ) are arranged in a laminate layer and the thickness of the module becomes thick. The flexible lead ( 15 ) is connected with the terminal sections ( 23 ) of the transparent substrate ( 1 ) and is connected with the circuit board ( 18 ). Therefore, the flexible lead ( 15 ) is connected to be turned back. Here, the effective connectable length of the terminal section is equal to or more than twice the connection length of the terminal section of the flexible lead ( 15 ). 
     Also, a thin film EL display unit is disclosed in the Japanese Laid Open Patent application (JP-A-Heisei 2-227989). In this conventional technique, like the above-mentioned conventional technique, an organic EL panel ( 10 ) and a printed circuit board ( 30 ) are arranged in a laminate layer. The flexible printed circuit board ( 40 ) turns back twice after connection with the organic EL panel ( 10 ) and is connected with the printed circuit board ( 30 ), and moreover, is turned back and is connected with the back of printed circuit board ( 30 ). In this conventional technique, there is a possibility that the wiring lines of the flexible printed circuit board ( 40 ) are broken. Also, in this structure, it is not possible to decrease the thickness of the film EL display unit. 
     Also, the connection structure of a flat display is disclosed in the Japanese Laid Open Patent application (JP-A-Heisei 6-230728). In this conventional technique, the flat display is composed of a flat display panel ( 1 ), a drive board ( 3 ), one side the flexible printed circuit board ( 14 ) and a connection cable ( 17 ). The one side the flexible printed circuit board ( 14 ) is provided with the printed circuits with a driver IC ( 6 ). The connection cable ( 17 ) is connected with the drive board ( 3 ), and is turned back twice and is connected with the one end of one side the flexible printed circuit board ( 14 ). The one side the flexible printed circuit board ( 14 ) connected with the connection cable ( 17 ) is connected with the driver IC ( 6 ) apart from the drive board ( 3 ) into a lateral direction. In this way, the connection cable ( 17 ) is bent like the character of S and is possibly broken. Also, because the driver IC ( 6 ) is apart from the drive board ( 3 ), the size in the lateral direction cannot be made small. 
     Also, an organic EL display is disclosed in Japanese Laid Open Patent Application (2000-3140). In this conventional technique, an organic EL display is composed of a substrate ( 1 ), an organic EL structure, a sealing plate ( 2 ) and a wiring line structure ( 3 ). The circuit for sealing plate ( 2 ) to do an organic EL structure at the sealing and to drive and to control an organic EL structure is prepared onto the superficies. The wiring line structure ( 3 ) connects the circuit which is formed on substrate ( 1 ) and the circuit of sealing plate ( 2 ). This wiring line structure ( 3 ) section is arranged in the position where sealing plate ( 2 ) on substrate ( 1 ) is not arranged. Moreover, the wiring line structure ( 3 ) has a circuit on an externally orientated surface. In this example, the wiring line structure ( 3 ) is composed of some portions and it is necessary to connect them. Also, the wiring line structure ( 3 ) and the sealing plate ( 2 ) are connected with the bonding wires. Therefore, the manufacturing method of the organic EL display takes large cost and time. Also, because the sealing plate ( 2 ) and the wiring line structure ( 3 ) are used, it is not possible to reduce the thickness of the organic EL display. 
     Also, a display unit is disclosed in Japanese Patent No. 2,612,968. In this conventional technique, a flexible printed circuit board is bent to be turned back from a support plate to a hard printed circuit board. Therefore, there is a fear that a wiring lien is broken. Also, a display panel drive circuit is mounted in the hard printed circuit board, and the hard printed circuit board is provided externally from the support plate in which a display panel is formed to a lateral direction. Therefore, there is a problem that the size to the lateral direction has become large compared with the display size of the display panel. 
     SUMMARY OF THE INVENTION 
     Therefore, an object of the present invention is to provide a flat panel display module which is made small and thin. 
     Another purpose of the present invention is to provide a manufacturing method of a flat panel display module, in which the number of steps can be reduced and also a process is easy so that the reduction in costs is possible. 
     Another purpose of the present invention is to provide a flat panel display module and a manufacturing method, in which a flexible printed circuit board is connected without being turned back. 
     Another purpose of the present invention is to provide a flat panel display module and a manufacturing method, in which break of a wiring line in a flexible printed circuit board can be prevented. 
     Another purpose of the present invention is to provide a flat panel display module and a manufacturing method, in which a flexible printed circuit board can be connected to a wiring line connection sections at both opposite ends. 
     Another purpose of the present invention is to provide a flat panel display module and a manufacturing method, in which it is possible to surely connect the flexible printed circuit board with very short terminals. 
     Another purpose of the present invention is to provide a flat panel display module and a manufacturing method, wherein the connection section of the flexible printed circuit board is supported. 
     Another purpose of the present invention is to provide a flat panel display module and a manufacturing method in which it is possible to apply to an organic EL unit. 
     In an aspect of the present invention, a flat panel display module includes a transparent substrate, a light emitting section, a sealing cap, a flexible printed circuit board and a semiconductor device. The transparent substrate with a wiring line terminal section is formed on one of surfaces of the transparent substrate in at least one of opposing ends of the transparent substrate. The light emitting section is provided in a display region in a center section on the surface on which the wiring line terminal section of the transparent substrate is formed. The sealing cap is provided for a sealing region to cover the light emitting section such that ends of the sealing cap does not reach the ends of the transparent substrate or the wiring line terminal section of the transparent substrate. The flexible printed circuit board is connected to the wiring line terminal section and extending along the sealing cap of the transparent substrate. The semiconductor device is mounted on the flexible printed circuit board for the light emitting section. 
     The semiconductor device may be mounted on a side of the flexible printed circuit board of the sealing cap. 
     Also, the flexible printed circuit board may have wiring line patterns for the semiconductor device on both sides thereof in a portion corresponding to the display region. 
     Also, the flexible printed circuit board may be provided to extend along the transparent substrate and the sealing cap without being turned back. 
     Also, the flexible printed circuit board may be bent at least twice between the wiring line terminal section and the display region such that the flexible printed circuit board is approximately parallel to the transparent substrate in the display region. In this case, the flexible printed circuit board may be bent to a first direction opposite to the transparent substrate in a first position between the wiring line terminal section of the transparent substrate and the sealing cap, may be bent to the first direction in a second position between the first position and the terminal section of the sealing cap, and may be bent to the second direction opposite to the first direction in a third position between the second position and the terminal section of the sealing cap. In this case, a bending angle in the first position is within 60 degrees. 
     Also, in the first position, the wiring line pattern of the flexible printed circuit board may be formed only on one side. In this case, in the second position, the wiring line pattern of the flexible printed circuit board may be formed on both sides and a resist film is applied. 
     Also, a bending angle in the second position may be within 90 degrees and a summation of the bending angle in the first position and the bending angle in the second position is desirably equal to or less than 90 degrees. 
     Also, the flexible printed circuit board may be bent to the second direction approximately parallel to the transparent substrate in the third position. 
     Also, a metal film may be formed on the back side of the flexible printed circuit board in one or both of the second position and the third position. 
     Also, the flexible printed circuit board may be bent to the first direction opposite to the transparent substrate in a fourth position between the end of the sealing cap and the end of the light emitting section, and may be bent to the second direction opposite to the first direction in a fifth position between the fourth position and the end of the light emitting section. In this case, in the fourth position, the wiring line patterns of the flexible printed circuit board may be formed on both sides of the flexible printed circuit board and a resist film is applied. 
     Also, the flexible printed circuit board may be bent to the second direction approximately parallel to the transparent substrate in the fifth position. 
     Also, the flat panel display module may further include a frame provided along the end of the transparent substrate. 
     Also, the frame may support the flexible printed circuit board together with the end of the sealing cap. 
     Also, the wiring line terminal section may be formed on both of the surface of the opposite ends of the transparent substrate, and the flexible printed circuit board is connected with the both of the wiring line terminal sections. 
     Also, the wiring line terminal section may be formed on both of the surface of the opposite ends of the transparent substrate, and the flexible printed circuit board is connected with the both of the wiring line terminal sections. 
     Also, the light emitting section may be an organic EL film. 
     Also, the light emitting section may be an organic EL film, and the flat panel display module may further include a desiccant section between the light emitting section and the sealing cap in a center section of the display region, the sealing cap has a protrusion section corresponding to the desiccant section. A plurality of the semiconductor devices may be provided on the flexible printed circuit board on a side of the transparent substrate between the protrusion section of the sealing cap and the end of the sealing cap. 
     In a second aspect of the present invention, a manufacturing method of a flat panel display module, is attained by (a) forming a display section, wherein the display section include a transparent substrate having a wiring line terminal section which is formed on one of surfaces of the transparent substrate in at least one of opposing ends of the transparent substrate; a light emitting section provided in a display region in a center section on the surface on which the wiring line terminal section of the transparent substrate is formed; a sealing cap provided for a sealing region to cover the light emitting section such that ends of the sealing cap does not reach the ends of the transparent substrate or the wiring line terminal section of the transparent substrate; a flexible printed circuit board connected to the wiring line terminal section and extending along the sealing cap of the transparent substrate; and a semiconductor device mounted on the flexible printed circuit board for the light emitting section; by (b) connecting the flexible printed circuit board with semiconductor devices mounted to the wiring line terminal section of the transparent substrate; and by (c) fixing a frame around the ends of the transparent substrate. 
     Also, the (b) connecting step may be attained by forming the flexible printed circuit board; and by mounting the semiconductor devices on the flexible printed circuit board. 
     Also, the (b) connecting step may be attained by mounting the semiconductor devices on the flexible printed circuit board; and by forming the flexible printed circuit board with the semiconductor devices mounted. 
     Also, the forming step of the flexible printed circuit board may be attained by bending the flexible printed circuit board to a first direction opposite to the transparent substrate in a first position between the end of the sealing cap of and the wiring line terminal section of the transparent substrate; by further bending the flexible printed circuit board to the first direction in a second position between the first position and the end of the sealing cap; and by bending the flexible printed circuit board to a second direction opposite to the first direction in a third position between the second position and the end of the sealing cap. 
     Also, a bending angle in the first position is equal to or less than 60 degrees, a bending angle in the second position is equal to or less than 90 degrees, and a summation of the bending angle in the first position and the bending angle in the second position is equal to or less than 90 degrees. 
     Also, the forming step of flexible printed circuit board may further include the steps of: bending the flexible printed circuit board to the first direction opposite to the transparent substrate in a fourth position between the end of the sealing cap and an end of the light emitting section; and bending the flexible printed circuit board to the second direction opposite to the first direction in a fifth position between the fourth position and the end of the light emitting section. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a back plan view showing the plane structure of a flat panel display module according to a first embodiment of the present invention; 
         FIG. 2  is a plan view showing a display section used in the flat panel display module according to the first embodiment of the present invention; 
         FIG. 3  is a cross sectional view showing a section along the long side of the flat panel display module according to the first embodiment of the present invention; 
         FIG. 4  is an expanded view showing a connection section of the flat panel display module according to the first embodiment of the present invention; 
         FIG. 5  is a partial cross sectional view showing a section according to the long side of the flat panel display module according to a second embodiment of the present invention; 
         FIG. 6  is a cross sectional view showing a section according to the long side of the flat panel display module according to a third embodiment of the present invention; and 
         FIG. 7  is an expanded view showing an expansion section of the connection section of the flat panel display module according to a fourth embodiment of the present invention. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Hereinafter, a flat panel display module of the present invention will be described with reference to the attached drawings. Here, in the flat panel display module  1  of the present invention, an organic EL (electro-luminescence) device is referred to as a display device. However, the display device is not limited to the organic EL device. 
       FIG. 1  is a back plan view of the flat panel display module according to the first embodiment of the present invention from the side of the back.  FIG. 2  is a diagram showing a display section used in the flat panel display module  1  shown in FIG.  1 .  FIG. 3  is a cross sectional view of the flat panel display module shown in  FIG. 1  in the longitudinal direction. 
     Referring to  FIG. 1 , FIG.  2  and  FIG. 3 , the flat panel display module  1  of the present invention is composed of the display section, a flexible printed circuit board  15  and a frame  16 . The display section is composed of a transparent substrate  11 , a display section  12 , a sealing cap  13 . 
     Referring to  FIG. 1 , the flat panel display module  1  according to the first embodiment of the present invention has a approximately rectangular shape, and a the wiring line section for connection to an external unit extends from the center of one of long sides. A display region is provided in the region within the sealing cap at the display section and a plurality of semiconductor devices  18  are arranged around the convex section at a the desiccant section in the center of the sealing cap. These semiconductor devices are provided to process the signals inputted from the wiring line section for the connection to the external unit and to drive the display section. 
     In  FIG. 1 , one chain line gives an outline of the bent positions when the flexible printed circuit board  15  is bent. 
     The transparent substrate  11  is composed of such a transparent member as a glass plate. The shape of the transparent substrate  11  is a rectangle substantively in this example. However, the shape is not limited to it. Referring to  FIG. 2 , the lower surface section of the transparent substrate  11  has a display region  41  and three the wiring line terminal sections  21 ,  22  and  23 . 
     The terminal region  21  is provided for an end of the long side section which is opposite to the wiring line section for the external connection in the lower side of the transparent substrate  11 . The wiring line terminal sections  22  and  23  are provided for ends of the two shorter side sections of the transparent substrate  11  respectively. The display region  41  is provided in the central section on the lower side section of the transparent substrate  11 . In this example, the shape of the display region  41  is a rectangle substantively. The display section is driven in a matrix manner in response to drive signals supplied to the wiring line terminal sections  21 ,  22  and  23  from the semiconductor device. In this way, a desired image is displayed and an image can be seen through the transparent substrate  11 . 
       FIG. 3  shows the structure of the lower side section of the transparent substrate  11 . Referring to  FIG. 3 , a light emitting section  12  is composed of an organic EL device in this example. The emitting light section  12  is formed in the display region  41  of the transparent substrate  11  to have a predetermined thickness. The organic EL device is driven by the semiconductor device  18  and emits light. To protect the organic EL device against moisture, the desiccant section  17  is generally provided onto the organic EL device. 
     A sealing cap  13  is formed on the lower side section of the transparent substrate  11  to cover the light emitting section  12  and the desiccant section  17 , and also to cover the transparent substrate  11  around the light emitting section  12 . However, the ends of the sealing cap  13  do not reach the ends of the transparent substrate  11 . The plane shape of the sealing cap  13  is a rectangle approximately in this example. Also, the sealing cap  13  has an approximately uniform thickness. 
     The sealing cap  13  has a first convex section below. The shape of this first convex section corresponds to the shape of the display region  41  and is larger than the shape of the display region  24 . Also, the sealing cap  13  has the second convex section which protrudes from the first convex section far below. The shape of this second convex section corresponds to the desiccant section  17  and has the shape which is rather larger than the desiccant section  17 . When the desiccant section  17  is unnecessary, of course, the second convex section does not exist. The plane of the lower side section of the first convex section and the plane of the lower side section of the second convex section in the sealing cap  13  are parallel to the plane of the transparent substrate  11  approximately. 
     The semiconductor devices  18  are mounted on the flexible printed circuit board  15 . The semiconductor devices  18  are composed of a signal generating circuit to generate drive signals based on the input signal from the wiring line section for the external connection and a drive circuit to drive the light emitting section  12  based on the drive signals. However, depending on the circuit structure, only the drive circuit it is needed. 
     Referring to  FIG. 1 , the shape of the flexible printed circuit board  15  is rectangular approximately. However, the wiring line section for the external the wiring lines extend from the center section of the one of the long side. The wiring line terminal section  31  composed of the terminals which are connected with the terminals which are provided for the wiring line terminal section  21  of the transparent substrate  11  is provided for the other end of the long side of the flexible printed circuit board  15 . Also, the wiring line terminal sections  32  and  33  which composed of the terminals connected with the terminals which are provided for the wiring line terminal sections  22  and  23  of the transparent substrate  11  are provided for the ends of the two shorter sides where the flexible printed circuit board  15  is opposite. 
     Also, in the flexible printed circuit board  15 , a cut-out portion is formed in each of the corner sections between the long side sections and the shorter side sections. These cut-out portions are provided not to give influence to the long side section or the shorter side section when the long side section or shorter side section of the flexible printed circuit board  15  is bent. 
     The flexible printed circuit board  15  is connected with the wiring line terminal sections  21 ,  22  and  23  of the transparent substrate  11  at the wiring line terminal sections  31 ,  32  and  33 . At this time, a wiring line terminal section is pressed and connected at the A section. In this way, the flexible printed circuit board  15  is arranged along the outer surface of the sealing cap  13  without being bent to be turned back. 
     Also, the upper surface section of the flexible printed circuit board  15  has a first region opposite to the lower side section of the first convex section of the sealing cap  13  and a second region opposite the lower side section of the second convex section of the sealing cap  13  when the flat panel display module is formed. The first region corresponds to the display region and is located in the center section of the surface section of the flexible printed circuit board  15 . Also, the second region corresponds to the desiccant section  17  and is in the center of the first region. 
     Also, the plurality of semiconductor devices  18  are provided in the first region other than the second region in the surface section of the flexible printed circuit board  15  to drive the light emitting section  12 . These semiconductor devices are connected using the wiring line pattern formed on the both sides of the flexible printed circuit board  15 . Here, a resist film is applied onto the wiring line pattern. 
     Of these semiconductor devices  18 , a drive circuit element is connected with the terminals of the wiring line terminal sections  31 ,  32  and  33  which were formed on the surface section of the flexible printed circuit board  15 . The terminals in the wiring line terminal sections  31 ,  32  and  33  and the terminals in the wiring line terminal sections  21 ,  22  and  23  formed on the lower side section of the transparent substrate  11  are pressed and connected. These circuits allow to the drive signals to be supplied to the light emitting section  12 . 
     Next, the connection of the flexible printed circuit board  15  to the transparent substrate  11  will be described below. 
     The length of each terminal in the wiring line terminal sections  21 ,  22  and  23  of the transparent substrate  11  is as very short as about 1.8 mm. Also, the pitch between the terminals is 0.088 mm in the wiring line terminal section  21  and is 0.272 mm in the wiring line terminal sections  22  and  23 . The sealing cap  13  is formed to a near portion to the wiring line terminal sections  21 ,  22  and  23 . 
       FIG. 4  is an expanded drawing of the connection section of the flexible printed circuit board  15  to the transparent substrate  11 . Referring to  FIG. 4 , the wiring line patterns are basically printed on the both sides in the flexible printed circuit board. An insulative resist is applied onto the wiring line pattern. However, the wiring line pattern is formed only on the one side in the wiring line terminal section  31  on the long side of the flexible printed circuit board  15  and the wiring line terminal sections  32  and  33  on the shorter side, and a resist is not applied. 
     The length of the terminal of the wiring line terminal sections  31 ,  32  and  33  is equal to or less than 1.8 mm, as described above. In this example, the flexible printed circuit board  15  is bent to the first direction to leave the transparent substrate  11  in the first position  51  apart from the end by 1 mm. Therefore, the length for the flexible printed circuit board  15  to be pressed and connected to the transparent substrate  11  is about 1 mm and it is very narrow. It is easy for the flexible printed circuit board  15  to be peeled off the transparent substrate  11 . If the flexible printed circuit board  15  is turned back as in the conventional example, the unnecessary force acts on the connection point A so that the flexible printed circuit board  15  has been easily peeled off the transparent substrate  11 . 
     In the first position  51 , the flexible printed circuit board  15  is further bent to the first direction at the angle within 60 degrees. In the first position  51 , as described above, the wiring line pattern is formed only on the one side and any resist layer is not applied. Therefore, when the flexible printed circuit board  15  is bent to the too large angle at a time, there is fear that the wiring line is broken. Therefore, it is desirable that the bend angle is equal to or less than 60 degrees. In this example, the flexible printed circuit board  15  is bent by the 30 degrees. 
     Next, the flexible printed circuit board  15  is bent to the first direction in the second position  52  between the first position  51  and the sealing cap  13 . In this position, the flexible printed circuit board may have the wiring line patterns on the both sides and may have the wiring line pattern on the one side. In any case, a resist layer is applied onto the wiring line pattern. The bending angle in the second position  52  is within 90 degrees. Because the resist layer is applied to this position even if the flexible printed circuit board  15  is supposed to have been bent at the larger angle, the wiring line is never broken. Also, it should be avoided that the flexible printed circuit board  15  is bent to turn back, such that unnecessary force acts on the connection section of the wiring line terminal section, as described above. Therefore, the bending angle in the second position  52  is desirably within 90 degrees. Also, it is desirable that a summation of the bending angle in the first position  51  and the bending angle in the second position  52  do not exceed 90 degrees. In this example, the bending angle in the second position  52  is about 60 degrees. 
     The flexible printed circuit board  15  is bent to the direction parallel to the transparent substrate  11  approximately in a third position  53  with the height which is approximately equal to the thickness of the sealing cap  13 . It should be noted that the resist layer is applied to the flexible printed circuit board  15  on the side of the center in the display region from the second position  52 . It is desirable that the flexible printed circuit board has a metal film on at least one side (on the back side in this example) of the circuit board, in one or both of the second position and the third position such that the plastic deformation property is increased at the bending position. The back plane of the flexible printed circuit board means a plane in which the wiring line pattern is not formed. Also, it is desirable that the metal film is formed on the whole back plane. The wiring line pattern is a metal film but separated from the metal film. 
     The flexible printed circuit board  15  is bent to the first direction in a fourth position  54  between the end of the sealing cap  13  and the end of the light emitting section  12 . Moreover, the flexible printed circuit board  15  is bent to be parallel to the transparent substrate  11  in a fifth position  55  corresponding to the maximum height of the sealing cap  13 . 
     The bending or forming process as described above is carried out respectively on the side of the long side and the shorter side in the flexible printed circuit board  15 . In this way, the flexible printed circuit board  15  is arranged along the outer surface of the sealing cap  13  from one of the shorter sides to the other thereof in one of the surfaces of the transparent substrate  11  without being bent to be turned back. At this time, the space where it is possible for the semiconductor devices  18  to be installed is secured in the region between the fourth position  54  and the display region. 
     After the flexible printed circuit board  15  is arranged, the frame  16  is arranged along the ends of the transparent substrate  11 . The frame  16  has a section of the character “L” and the bottom section extends to the display region. If the upper surface of the bottom section has a contact with the sealing cap  13  in the B section between the third position  53  and the fourth position  54 , the flexible printed circuit board  15  can be sandwiched and supported by the frame  16  and the sealing cap  13  in the B section. Therefore, it is possible to prevent that unnecessary force acts on the connection section in the wiring line terminal sections  31 ,  32  and  33 . In this case, even if the total bending angle including the bending angle in the second position  52  gets to be near 90 degrees or exceeds 90 degrees little, there is no case that the wiring line terminal sections  31 ,  32  and  33  peel off the wiring line terminal sections  21 ,  22  and  23  of the transparent substrate  11 . 
     At this time, depending on the processing precision, there is a case that the flexible printed circuit board  15  cannot be sandwiched or supported by the sealing cap  13  and the frame  16 . In such a case, an insulating filling film may be inserted between the sealing cap  13  and the frame  16 . 
     Next, the method of manufacturing a flat panel display module of the present invention will be described below. 
     First, the light emitting section  12  is formed on the transparent substrate  11 , and the light emitting section  12  is sealed by the sealing cap  13  so as to complete the display section. Next, the flexible printed circuit board  15  as described above is prepared. The semiconductor devices are mounted on predetermined positions of the flexible printed circuit board  15 . The flexible printed circuit board  15  is pressed and connected on the wiring line terminal sections  21 ,  22  and  33  of the transparent substrate  11  in the wiring line terminal sections  31 ,  32  and  33 . After that, the frame  16  is installed to the transparent substrate  11 . At this time, it is desirable to sandwich and support the flexible printed circuit board  15  by the sealing cap  13  and the frame  16  as described above. In this way, the flat panel display module is completed. 
     It should be noted that the flexible printed circuit board  15  may be bent before the semiconductor devices  18  are mounted thereon or after the semiconductor devices  18  are mounted thereon. 
     Next, the flat panel display module in the second embodiment of the present invention will be described.  FIG. 5  is a cross section view of the flat panel display module in the second embodiment of the present invention. 
     Referring to  FIG. 5 , in the second embodiment, the bent shape of the flexible printed circuit board  15  is same as the first embodiment. However, the flexible printed circuit board  15  has the wiring line terminal sections  31  and  32  but does not have the wiring line terminal section  33 . The semiconductor devices are arranged in the sealing region on the side of the wiring line terminal section  32  and the sealing region on the side of the wiring line terminal section  33 . Here, the sealing region is the region corresponding to the first convex section of the sealing cap  13  other than the second convex section. On the shorter side of the flexible printed circuit board  15 , the flexible printed circuit board  15  is supported by the sealing cap  13  in the sealing region and the frame  16 . 
     Next, the flat panel display module in the third embodiment of the present invention will be described.  FIG. 6  is a cross sectional view of the flat panel display module in the third embodiment of the present invention. 
     Referring to  FIG. 6 , in the third embodiment, the flexible printed circuit board  15  has the wiring line terminal sections  31  and  32  but does not have the wiring line terminal section  33 . Also, the semiconductor devices are arranged only in the sealing region on the side of the wiring line terminal section  32 . On the side of the long side of the flexible printed circuit board  15 , the bent shape of the flexible printed circuit board is same as the first embodiment. Therefore, the flexible printed circuit board  15  is supported by the sealing cap  13  in the display region and the frame  16 . 
     Also, on the side of the wiring line terminal section  32  of the flexible printed circuit board  15 , the bent shape of the flexible printed circuit board is same as the first embodiment. Therefore, the flexible printed circuit board  15  is supported by the sealing cap  13  in the display region and the frame  16 . However, the flexible printed circuit board  15  is bent to extend along the second convex section and the first convex section of the sealing cap  13  on the side of the shorter side corresponding to the wiring line terminal section  32 . Also, the flexible printed circuit board  15  is sandwiched and supported in the C section by a section corresponding to the display region of the sealing cap  13  and the frame  16 . 
     Next, the flat panel display module in the fourth embodiment of the present invention will be described.  FIG. 7  is a cross sectional view of the flat panel display module in the fourth embodiment of the present invention. 
     Referring to  FIG. 7 , in the fourth embodiment, the bending process is not carried out to the flexible printed circuit board  15  in the fourth and the fifth position. Also, the height of the third position from the transparent substrate  11  is set to be equal to the height of the fifth position. Therefore, the flexible printed circuit board  15  is never sandwiched and supported by the frame  16  and the sealing cap  13 . Therefore, force acts directly on the connection section, but there is a merit that the semiconductor device mounting section can be widely used. 
     As mentioned above, according to the flat panel display module of the present invention, the flexible printed circuit board is connected to the connection terminal section of the transparent substrate without being turned back. Therefore, there is no fear that unnecessary force acts on the connection section so that the flexible printed circuit board is peeled off the transparent substrate. Also, even if the width of the connection section is narrow, it is difficult for unnecessary force to act, because the flexible printed circuit board is arranged along the connection section. Therefore, the flexible printed circuit board is bent to have a small angle at first, and is next bent to have the larger angle. 
     In case of this bending process, the wiring line pattern is never broken because the bending angle is small in the first bending section. Also, there is not fear that the wiring line pattern is broken because the wiring line pattern is protected by the resist layer in this section although the bend angle is large in the next bending section. 
     Also, because the flexible printed circuit board is sandwiched and supported by the frame and the sealing cap, it is difficult for the force to act on the connection section. 
     Also, the semiconductor device to drive the light emitting section such as the organic EL device is provided for the free space from the sealing cap for protecting the light emitting section on the side of the light emitting section of the flexible printed circuit board. Therefore, the semiconductor device never protrudes and the flat panel display module can be made thin. 
     In this way, according to the present invention, the flat panel display module can be made small and thin. Moreover, as mentioned above, to prevent break of the wiring line pattern due to the bending process, the flexible printed circuit board is previously bent. Thus, it is possible to provide the flat panel display module which has sure connection in a small number of steps.