Abstract:
A substantially rectangle shaped frame for rigidly affixing a flat-shaped electrode unit to a rear panel at intermediate parts of the frame and elastically attaching the frame to the rear panel by a resilient retaining member at four corners of the frame, thereby, stabilizing an engagement between the rear panel and the flat-shaped electrode unit via the frame regardless of difference in degrees of deformations thereamong.

Description:
FIELD OF THE INVENTION AND RELATED ART STATEMENT 
     1. Field of the Invention 
     The present invention relates to a flat image display apparatus which is to be used in a television receiver and a display unit for computers or the like. 
     2. Description of the Prior Art 
     In recent years, a color image display apparatus has been developed for achieving a compact size. 
     In an electron beam scanning type of color image display apparatus, a flat type image display apparatus is disclosed in unexamined published Japanese application (TOKKAI) HEI 3-67444. This type of flat image display apparatus is generally characterized as follows: 
     (1) A distance between a cathode and an anode is remarkably shorter than that of a conventional cathode-ray tube type. 
     (2) A fluorescent screen is divided horizontally and vertically into matrix arrangement of plurality of plural small segments, and each of the small segments is scanned by deflecting one electron beam which is separated from the other electron beams. 
     (3) Fluorescent dots of R (red), G (green) and B (blue) for one picture element in the small segment are shot in turn by the electron beam. The amount of irradiation is controlled by color picture signals. 
     (4) Television moving pictures as a whole are reproduced on the fluorescent screen by arranging all of the small segments. 
     The flat type image display apparatus generally comprises a flat box-shaped vacuum case including plural linear hot cathodes and a flat-shaped electrode unit. Each linear hot cathode (hereinafter referred to as &#34;linear cathode&#34;) serves as a generator of the electron beam. The flat-shaped electrode unit has plural holes and plural slits for deflecting, focussing and controlling the electron beam. The electron beam emitted from each linear cathode passes through the holes and the slits. Thereby, the electron beam reaches the fluorescent screen via the above-mentioned steps of deflecting, focussing and controlling. As a result, the fluorescent screen emits light, and a television moving picture is reproduced on the fluorescent screen. 
     A concrete construction of the general flat type image display apparatus will be elucidated with reference to FIG. 8, FIG. 9 and FIG. 10. In the description of the prior art, a horizontal direction is shown by an arrow &#34;X&#34; of FIG. 8, and a vertical direction is shown by an arrow &#34;Y&#34; of FIG. 8. FIG. 8 is a perspective view showing the flat type image display apparatus. FIG. 9 is a cutaway perspective view, which is taken on line IX--IX of FIG. 8, showing a part of the flat type image display apparatus. FIG. 10 is an exploded perspective view showing the general construction of a main part of the flat type image display apparatus. 
     As shown in FIG. 8, the flat type image display apparatus 100 has a vacuum case constituted by a front housing 1 and a rear panel 2. The front housing 1 and the rear panel 2 are made of glass which has a predetermined thickness, for example, 10 mm. Peripheral parts of the front housing 1 are fixed to the rear panel 2 by a bonding glass member 3, such as a soldering glass. The melting point of the bonding glass member 3 is selected lower than that of the front housing 1 or the rear panel 2, and the bonding glass member 3 seals the vacuum case via a melting and recrystallization An evacuation pipe 4 for evacuating the vacuum case and a high voltage terminal 5 of the anode are provided on the edge of the front housing 1. Plural output terminals 6 are led out of the vacuum case through the bonding glass member 3. 
     As shown in FIG. 9, one end of each of the plural output terminals 6 is connected to a flat-shaped electrode unit 7. In order to use the flat type image display apparatus 100 as a television receiver or a display unit of a computer, the other end of each of the plural output terminals 6 is connected to external circuits (not shown), for example, a driving circuit and signal processing circuit. 
     The flat-shaped electrode unit 7 is constituted by plural flat-shaped electrodes 7a-7g (FIG. 10). At four corners of the flat-shaped electrode unit 7, four securing screws 8a-8d (FIG. 11) set the flat-shaped electrode unit 7 on a conventional supporting unit 14 (FIG. 11), respectively. The flat-shaped electrodes 7a-7g (FIG. 10) are made of an alloy, such as Ni and Fe (Ni:Fe=36%:64%). 
     As shown in FIG. 10, the main part of the flat type image display apparatus 100 comprises a back electrode 9, plural linear cathodes 10a-10c and the flat-shaped electrode unit 7. The back electrode 9, plural linear cathodes 10a-10c and the flat-shaped electrode unit 7 are provided from the rear panel 2 toward the front housing 1. The back electrode 9 is mounted on the inner surface of the rear panel 2. The linear cathodes 10a-10c are horizontally stretched so as to be in parallel with the back electrode 9. The linear cathodes 10a-10c act as an electron beam source. Although only three pieces of the linear cathodes 10a-10c are shown in FIG. 10, there are actually many linear cathodes (e.g. 44 pieces). 
     The flat-shaped electrode unit 7 comprises an electron beam extracting electrode 7a, a modulation electrode 7b, a vertical focussing electrode 7c, a horizontal focussing electrode 7d, a horizontal deflection electrode 7e, a shield electrode 7f and a vertical deflection electrode 7g. The respective electrodes 7a-7g are bonded with each other keeping respective predetermined gaps held therebetween, and they are electrically insulated from each other by respective vitreous insulators (not shown). 
     As shown in FIG. 10, the electrons emitted from the linear cathode 10b are conducted by an extracting hole 11 of the electron beam extracting electrode 7a to form the electron beam 12. Thereafter, the electron beam 12 passes through holes and slits of the other electrodes 7b, 7c, 7d, 7e, 7f and 7g, thereby being focussed and deflected. Finally, the electron beam 12 reaches a small segment 13a of a fluorescent screen 13 formed on the inner surface of the front housing 1. Many fluorescent dots of R, G and B colors are provided on the small segment 13a by printing and coating. The small segment 13a emits light when the electron beam 12 lands on the fluorescent dots of the small segment 13a. Similarly, other electron beams land on the fluorescent dots of other small segments, and every small segment emits light. As a result, the television moving picture is reproduced on the fluorescent screen 13. In FIG. 10, although the fluorescent screen 13 is divided into only 3 pieces in a vertical line and only 7 pieces in a horizontal line, the fluorescent screen 13 is actually divided into many small segments, such as 44 pieces in the vertical line and 221 pieces in the horizontal line, a total of 9724 pieces. 
     The conventional supporting unit 14 for the flat-shaped electrode unit 7 will be elucidated with reference to FIG. 11 and FIG. 12. FIG. 11 is an explanatory view showing a conventional supporting unit for the flat-shaped electrode unit. FIG. 12 is a partially sectional view, which is taken on line Z--Z of FIG. 8, showing the mounting construction of the conventional supporting unit at a corner part of the flat type image display apparatus. 
     As shown in FIG. 11, the conventional supporting unit 14 for the flat-shaped electrode unit 7 comprises six setting mounts 15a-15f, a pair of securing members 16a and 16b and a pair of supporting members 17a and 17b. The six setting mounts 15a-15f are made of an alloy, such as Ni and Fe (Ni:Fe=50%:50%), and fixed on a predetermined position of the rear panel 2 by a bonding glass member 19 (FIG. 12) so as to surround the back electrode 9 (shown in two-dot chain line). The melting point of the bonding glass member 19 is selected lower than that of the rear panel 2. 
     The securing members 16a and 16b are also made of the alloy, such as Ni and Fe (Ni:Fe=50%:50%), and are located in parallel with each other in the vertical direction. Two securing screws 18a and 18b are set at both end parts of the securing member 16a on the setting mounts 15a and 15b, respectively. Similarly, securing screws 18d and 18e are set at both end parts of the securing member 16b on the setting mounts 15d and 15e, respectively. 
     The supporting members 17a and 17b are also made of the alloy, such as Ni and Fe (NI:Fe=50%:50%), and are located in parallel with each other in the horizontal direction. A securing screw 18c sets the intermediate part of the supporting member 17a on the setting mount 15c so that both ends of the supporting member 17a are put on one end of the securing members 16a and 16b, respectively. Similarly, a securing screw 18f sets the intermediate part of the supporting member 17b on the setting mount 15f so that both ends of the supporting member 17b are put on the other end of the securing member 16a and 16b, respectively. 
     As a result, as shown in FIG. 11, the respective ends of the supporting members 17a and 17b are put on the respective ends of the securing members 16a and 16b. Thereby, the securing members 16a and 16b and the supporting members 17a and 17b form a rectangle shaped frame on the six setting mounts 15a-15f. 
     An insulating film 20 (FIG. 12) is provided on the upper surface of the supporting members 17a and 17b, and the flat-shaped electrode unit 7 (FIG. 10) is disposed further thereon. At four corners of the supporting unit 14, the flat-shaped electrode unit 7, the supporting members 17a and 17b and the securing members 16a and 16b are fixed to each other by four securing screws 8a-8d. 
     As shown in FIG. 11, a securing position of the securing screw 8a is located at the part outside with respect to the setting mount 15a in relation to the center part of the rear panel 2, and a securing position of the securing screw 8b is located at the part outside with respect to the setting mount 15b in relation to the center part of the rear panel 2. Similarly, a securing position of the securing screw 8c is located at the part outside with respect to the setting mount 15d in relation to the center part of the rear panel 2, and a securing position of the securing screw 8d is located at the part outside with respect to the setting mount 15e in relation to the center part of the rear panel 2. 
     As shown in FIG. 12, each of the flat-shaped electrodes 7a-7g of the flat-shaped electrode unit 7 is disposed in a predetermined position between the back electrode 9 and the fluorescent screen 13 by the conventional supporting unit 14. Insulating washers 21 are provided between every two flat-shaped electrodes around the securing screws 8a. A metal-backed layer 22 is provided on the inner surface of the fluorescent screen 13. 
     In the flat type image display apparatus 100, in order to obtain a high definition image, the electron beam is required to make an exact scanning on the fluorescent screen 13 without mislanding. Therefore, it is necessary that the supporting unit 14 holds the flat-shaped electrode unit 7 at the predetermined position with precision of a micron order. 
     However, the flat type image display apparatus 100 is repeatedly exposed to a high temperature during the manufacturing process and heated until completion of its assembly as follows: 
     (1) When the setting mounts 15a-15f are fixed on the rear panel 2 by the bonding glass member 19, the bonding glass member 19 is heated and melted in a baking oven at the temperature of about 500° C. 
     (2) When the front housing 1 is fixed to the rear panel 2 by the bonding glass member 3, the bonding glass member 3 is heated and melted in the baking oven at the temperature of about 500° C. 
     (3) When an inside space of the flat type image display apparatus 100 is evacuated by using the evacuation pipe 4, the flat type image display apparatus 100 is put in the baking oven at the temperature of 300° C. to 350° C. 
     Furthermore, since the linear cathode 10 is heated at the temperature of 600° C. to 700° C. for generating the electron beam, the inside space is exposed to radiation from linear cathode 10 during the operation of the flat type image display apparatus 100. 
     As a result, thermal deformations caused by the above-mentioned heating are generated in the flat type image display apparatus 100. The rear panel 2, the flat-shaped electrode unit 7 and the frame of the conventional supporting unit 14 are made of different materials from each other. Namely, in the rear panel 2, the flat-shaped electrode unit 7 and the frame of the conventional supporting unit 14, degrees of the thermal deformations are different from each other because of differences of coefficient of thermal expansion and thermal capacity. When the flat type image display apparatus 100 is heated, degrees of the thermal deformations become larger in order of the frame of the conventional supporting unit 14, the rear panel 2 and the flat-shaped electrode unit 7. 
     Furthermore, in the conventional supporting unit 14, it is impossible to minimize undesirable influences of a difference in degrees of thermal deformations caused by the above-mentioned heating completely. Therefore, in the flat type image display apparatus 100, some cracks and warps are generated at strength-weak points or collecting points of thermal stress by a thermal expansion. 
     Thereby, the conventional supporting unit 14 can not hold the flat-shaped electrode unit 7 at the predetermined position precisely. As a result, it is impossible to make an exactly scanning of the electron beam on the fluorescent screen 13. Accordingly, there is a problem that the high definition image is not reproduced on the fluorescent screen 13. 
     A concrete example of thermal deformation caused by the aforementioned heating will be elucidated with reference to FIG. 11 and FIG. 12. 
     In FIG. 11, when the flat type image display apparatus 100 is heated, the rear panel 2 is expanded into the rear panel 2&#39; shown by dashed lines. Similarly, the supporting members 17a and 17b are deformed into the supporting members 17a&#39; and 17b&#39; shown by dashed lines, respectively. Plural arrows A, B, C, D,-P designate respective directions of the thermal deformation of the rear panel 2. In order to understand the thermal deformation easily, the rear panel 2&#39; and the supporting members 17a&#39; and 17b&#39; are shown in FIG. 11 exaggeratedly. 
     As has been elucidated in the above, the flat-shaped electrode unit 7, the supporting members 17a and 17b and the securing members 16a and 16b are fixed to each other by four securing screws 8a-8d at four corners of the supporting unit 14. Therefore, in the securing members 16a and 16b and the supporting members 17a and 17b, those degrees of the thermal deformation are limited by the flat-shaped electrode unit 7 via the four securing 8a-8d. Furthermore, the intermediate parts of the supporting member 17a and 17b is fixed to the setting mounts 15c and 15f, respectively. Accordingly, the respective intermediate parts are deformed more than the respective end parts by the thermal deformation of the rear panel 2 as shown in FIG. 11. 
     Since the degree of the thermal deformation of the rear panel 2 is the largest at its four corners, cracks are most often generated at the setting mounts 15a, 15b, 15d and 15e. 
     A concrete example of the generation of cracks will be elucidated with reference to FIG. 12. 
     In FIG. 12, when the flat type image display apparatus 100 is heated, the securing member 16a and the rear panel 2 are deformed in directions shown by arrows S and R, respectively. However, the degree of the thermal deformation of the securing member 16a is larger than that of the rear panel 2. Therefore, cracks 23 are generated in the bonding glass member 19 and the rear panel 2. Cracks 23 are not always generated at the predetermined position and the predetermined degree. Therefore, in the prior art, an effective countermeasure has not been taken against plural cracks 23. 
     Furthermore, in the conventional supporting unit 14, it is necessary that the above-mentioned thermal deformations be taken into consideration. Therefore, precision of respective sizes of the securing members 16a and 16b and the supporting members 17a and 17b becomes severe, and the assembly of the conventional supporting unit 14 receives much time. As a result, cost of the flat type image display apparatus 100 is inevitably high. 
     Furthermore, when the inside space of the flat type image display apparatus 100 is evacuated by using the evacuation pipe 4, the central part of the rear panel 2 is deformed toward the front housing 1. However, in the conventional supporting unit 14, there is no consideration for this deformation. Therefore, the conventional supporting unit 14 can not hold the flat-shaped electrode unit 7 at the predetermined position precisely after the inside space of the flat type image display apparatus 100 is evacuated. 
     OBJECT AND SUMMARY OF THE INVENTION 
     The object of the present invention is to provide a flat type image display apparatus that can solve the aforementioned problems. 
     In order to achieve the above-mentioned object, a flat type image display apparatus in accordance with the present invention comprises: 
     a vacuum case having a front housing and a rear panel; 
     a fluorescent screen formed on an inner surface of the front housing; 
     a back electrode formed on an inner surface of the rear panel; 
     plural linear cathodes for emitting electron beams; 
     a flat-shaped electrode unit for deflecting, focussing and controlling the electron beams; and 
     a supporting unit for holding the flat-shaped electrode unit and having a substantially rectangle shaped frame and resilient retaining. The substantially rectangle shaped frame holds the flat-shaped electrode unit, wherein four intermediate parts of the substantially rectangle shaped frame are fixed to the rear panel. Four corners of the substantially rectangle shaped frame are held elastically with each other by the resilient retaining means. By means of the resilient retaining means, an engagement between the rear panel and the flat-shaped electrode unit via the supporting unit is stably retained regardless of difference in degrees of deformations thereamong. 
     In the flat type image display apparatus of the present invention, the substantially rectangle shaped frame, which holds the flat-shaped electrode unit, is fixed to the rear panel at four intermediate parts of the frame; and the frame is elastically held by the resilient retaining means at four corners of the frame. Furthermore, the resilient retaining means eliminates adverse influences of, or absorbs, a difference in degrees of deformations among the rear panel, the flat-shaped electrode unit and the frame. In general at the four corners of the frame the differences the positional difference due to thermal deformations among the rear panel, the flat-shaped electrode unit and the frame are most. Furthermore, the resilient retaining means absorbs most the difference without giving an undesirable stress to the flat-shaped electrode unit. As a result, it is possible to make an exact scan of the electron beam on the fluorescent screen. Accordingly, a high definition image can be reproduced on the fluorescent screen. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is an explanatory view showing a supporting unit for a flat-shaped electrode unit in accordance with the present invention, 
     FIG. 2 is an exploded perspective view showing the construction of the supporting unit in accordance with the present invention, 
     FIG. 3 is a partially sectional view, which is taken on line Z--Z of FIG. 8, showing the mounting construction of the supporting unit of the present invention at a corner part of the flat type image display apparatus, 
     FIG. 4A is an enlarged view of welding parts between the securing member 53a and the setting mount 52b, 
     FIG. 4B is a sectional view, which is taken on line W--W of FIG. 4A, showing welding parts between the securing member 53a and the setting mount 52b, 
     FIG. 5 is an enlarged view showing resilient retaining means of the present invention, 
     FIG. 6 is a lateral view showing the supporting unit in accordance with the present invention, 
     FIG. 7 is a front view of a modified version of the supporting unit in accordance with the preferred embodiment of the present invention, 
     FIG. 8 is a perspective view showing the flat type image display apparatus, 
     FIG. 9 is a cutaway perspective view, which is taken on line IX--IX of FIG. 8, showing a part of the flat type image display apparatus, 
     FIG. 10 is an exploded perspective view showing general construction of a main part of the flat type image display apparatus, 
     FIG. 11 is an explanatory view showing a conventional supporting unit for the flat-shaped electrode unit; and 
     FIG. 12 is a partially sectional view, which is taken on line Z--Z of FIG. 8, showing the mounting construction of the conventional supporting unit at a corner part of the flat type image display apparatus. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Hereafter, a preferred embodiment of the present invention is described with reference to the accompanying drawings. 
     First, a concrete construction of the general flat type image display apparatus will be elucidated with reference to FIG. 8, FIG. 9 and FIG. 10. In the description of the present invention, a horizontal direction is shown by an arrow &#34;X&#34; of FIG. 8, and a vertical direction is shown by an arrow &#34;Y&#34; of FIG. 8. FIG. 8 is a perspective view showing the flat type image display apparatus. FIG. 9 is a cutaway perspective view, which is taken on line IX--IX of FIG. 8, showing a part of the flat type image display apparatus. FIG. 10 is an exploded perspective view showing the general construction of a main part of the flat type image display apparatus. 
     As shown in FIG. 8, the flat type image display apparatus 100 has a vacuum case constituted by a front housing 1 and a rear panel 2. The front housing 1 and the rear panel 2 are made of glass which has a predetermined thickness, for example, 10 mm. Peripheral parts of the front housing 1 are fixed to the rear panel 2 by a bonding glass member 3, such as a soldering glass. The melting point of the bonding glass member 3 is selected lower than that of the front housing 1 or the rear panel 2, and the bonding glass member 3 seals the vacuum case via a melting and recrystallization. An evacuation pipe 4 for evacuating the vacuum case and a high voltage terminal 5 of an anode are provided on the edge of the front housing 1. Plural output terminals 6 are led out of the vacuum case through the bonding glass member 3. 
     As shown in FIG. 9, one end of the plural output terminals 6 are connected with a flat-shaped electrode unit 7. In order to use the flat type image display apparatus 100 as a television receiver or a display unit of a computer, the other end of the plural output terminals 6 are connected with external circuits (not shown), for example, a driving circuit and signal processing circuit. 
     The flat-shaped electrode unit 7 is constituted by plural flat-shaped electrodes 7a-7g (FIG. 10). At four corners of the flat-shaped electrode unit 7, four securing screws 8a-8d (FIG. 1) set the flat-shaped electrode unit 7 on a supporting unit 51 (FIG. 1) of the present invention, respectively. The flat-shaped electrodes 7a-7g (FIG. 10) are made of an alloy, such as Ni and Fe (Ni:Fe=36%:64%). 
     As shown in FIG. 10, the main part of the flat type image display apparatus 100 comprises a back electrode 9, plural linear cathodes 10a-10c and the flat-shaped electrode unit 7. The back electrode 9, plural linear cathodes 10a-10c and the flat-shaped electrode unit 7 are provided from the rear panel 2 toward the front housing 1. The back electrode 9 is mounted on the inner surface of the rear panel 2. The linear cathodes 10a-10c are horizontally stretched by a pair of heat-resistant insulating frames 50a and 50b (FIG. 1) so as to be in parallel with the back electrode 9. The linear cathodes 10a-10c act as an electron beam source. Although only three pieces of the linear cathodes 10a-10c are shown in FIG. 10, there are actually many linear cathodes (e.g. 44 pieces). 
     The flat-shaped electrode unit 7 comprises an electron beam extracting electrode 7a, a modulation electrode 7b, a vertical focussing electrode 7c, a horizontal focussing electrode 7d, a horizontal deflection electrode 7e, a shield electrode 7f and a vertical deflection electrode 7g. The respective electrodes 7a-7g are bonded with each other keeping respective predetermined gaps held therebetween, and they are electrically insulated from each other by respective vitreous insulators (not shown). 
     As shown in FIG. 10, the electrons emitted from the linear cathode 10b are conducted by an extracting hole 11 of the electron beam extracting electrode 7a to form the electron beam 12. Thereafter, the electron beam 12 passes through holes and slits of the other electrodes 7b, 7c, 7d, 7e, 7f and 7g, thereby being focussed and deflected. Finally, the electron beam 12 reaches a small segment 13a of a fluorescent screen 13 formed on the inner surface of the front housing 1. Many fluorescent dots of R, G and B colors are provided on the small segment 13a by known printing process. The small segment 13a emits light when the electron beam 12 lands on the fluorescent dots of the small segment 13a. Similarly, other electron beams land on the fluorescent dots of other small segments, and every small segment emits light. As a result, a television moving picture is reproduced on the fluorescent screen 13. In FIG. 10, although the fluorescent screen 13 is divided into only 3 pieces in a vertical line and only 7 pieces in a horizontal line, the fluorescent screen 13 is actually divided into many small segments, such as 44 pieces in the vertical line and 221 pieces in the horizontal line, a total of 9724 pieces. 
     A concrete construction of the supporting unit 51 for the flat-shaped electrode unit 7 in accordance with the present invention will be elucidated with reference to FIG. 1, FIG. 2 and FIG. 3. FIG. 1 is an explanatory view showing a supporting unit for a flat-shaped electrode unit in accordance with the present invention. FIG. 2 is an exploded perspective view showing the construction of the supporting unit in accordance with the present invention. FIG. 3 is a partially sectional view, which is taken on line Z--Z of FIG. 8, showing the mounting construction of the supporting unit of the present invention at a corner part of the flat type image display apparatus. 
     As shown in FIG. 1 and FIG. 2, the supporting unit 51 for the flat-shaped electrode unit 7 in accordance with the present invention comprises eight setting mounts 52a-52h, a pair of securing members 53a and 53b, a pair of supporting members 54a and 54b, four tension plates 55a-55d, four spring plates 56a-56d and two spacers 57a and 57b. 
     The eight setting mounts 52a-52h are made of the alloy, such as Ni and Fe (Ni:Fe=50%:50%), and are fixed on a predetermined position of the rear panel 2 by a bonding glass member 19 so as to surround the back electrode 9 (shown in two-dot chain line). When the setting mounts 52a-52h are fixed on the rear panel 2 by the bonding glass member 19, the bonding glass member 19 is heated and melted in a baking oven at the temperature of about 500° C. The melting point of the bonding glass member 19 is selected lower than that of the rear panel 2. 
     The securing members 53a and 53b are made of the alloy, such as Ni and Fe (Ni:Fe=36%:64%), and are located in parallel with each other in the vertical direction. The securing member 53a is disposed on the setting mounts 52a, 52b and 52c. A first hole 53aa is formed at the intermediate part of the securing member 53a for welding the securing member 53a to the setting mount 52b. A second hole 53ab is formed at one end part of the securing member 53a for locating the tension plate 55a. A third hole 53ac is formed at the other end part of the securing member 53a for locating the tension plate 55b. 
     A concrete welding method in the first hole 53aa will be elucidated with reference to FIG. 4A and FIG. 4B. FIG. 4A is an enlarged view of welding parts between the securing member 53a and the setting mount 52b. FIG. 4B is a sectional view, which is taken on line 4B--4B of FIG. 4A, showing welding parts between the securing member 53a and the setting mount 52b. 
     As shown in the FIG. 4A and FIG. 4B, the bottom parts of the inner walls of the first hole 53aa are fixed to the upper surface of the setting mount 52b by welding, such as a laser welding. Because this welding of the securing member 53a is performed in the bottom parts of the first hole 53aa, plural welding parts 60 do not protrude above a level of the upper surface of the securing member 53a as shown in FIG. 4A and FIG. 4B. Thereby, it is possible to prevent an undesirable electromagnetic influence on plural parts 60 of the flat type image display apparatus 100. Thus, the intermediate part of the securing member 53a is fixed to the setting mount 52b at the first hole 53aa. 
     Similarly, the securing member 53b is disposed on the setting mounts 52e, 52f and 52g. A first hole 53ba is formed at the intermediate part of the securing member 53b for welding the securing member 53b to the setting mount 52f. A second hole 53bb is formed at one end part of the securing member 53b for locating the tension plate 55d. A third hole 53bc is formed at the other end part of the securing member 53b for locating the tension plate 55c. The intermediate part of the securing member 53b is fixed to the setting mount 52f at the first hole 53ba. 
     Furthermore, as shown in FIG. 1, both ends of the heat-resistant insulating frame 50a, shown by dashed lines, are fitted to both ends of the securing member 53a, respectively. Thereby, the heat-resistant insulating frame 50a is disposed in parallel with the securing member 53a in the vertical direction. Similarly, both ends of the heat-resistant insulating frame 50b shown by dashed lines are fitted to both ends of the securing member 53b, respectively. Thereby, the heat-resistant insulating frame 50b is disposed in parallel with the securing member 53b in the vertical direction. As a result, the plural linear cathodes 10 (FIG. 3) are stretched horizontally between the two heat-resistant insulating frames 50a and 50b in parallel with each other. 
     The supporting members 54a and 54b are also made of an alloy, such as Ni and Fe (Ni:Fe=36%:64%), and are located in parallel with each other in the horizontal direction. A first hole 54aa is formed at the intermediate part of the supporting member 54a for welding the supporting member 54a to the setting mount 52d. The intermediate part of the supporting member 54a is fixed to the setting mount 52d at the first hole 54aa via the spacer 57a. Similarly, a first hole 54ba is formed at the intermediate part of the supporting member 54b for welding the supporting member 54b to the setting mount 52h. The intermediate part of the supporting member 54b is fixed to the setting mount 52h at the first hole 54ba via the spacer 57b. 
     As shown in FIG. 1, both ends of the supporting member 54a are put on one end of the securing members 53a and 53b, and both ends of the supporting member 54b are put on the other end of the securing members 53a and 53b. Thereby, the securing members 53a and 53b and the supporting members 54a and 54b form a substantially rectangle shaped frame on the eight setting mounts 52a-52h. The securing members 53a and 53b and the supporting members 54a and 54b form supporting means. 
     As shown in FIG. 3, an insulating film 20 is provided on the upper surface of the supporting member 54a and 54b, and the flat-shaped electrode unit 7 (FIG. 10) is disposed further thereon. At the four corners of the supporting unit 51, the flat-shaped electrode unit 7, the securing members 53a and 53b and the supporting member 54a and 54b are fixed to each other by four securing screws 8a-8d. The insulating film 20 is formed on the upper surface of the securing members 53a and 53b, for example, by thermal spraying of an alumina. 
     As shown in FIG. 1 and FIG. 3, a securing position of the securing screw 8a is located at the part outside with respect to the setting mount 52a in relation to the center part of the rear panel 2, and a securing position of the securing screw 8b is located at the part outside with respect to the setting mount 52c in relation to the center part of the rear panel 2. Similarly, a securing position of the securing screw 8c is located at the part outside with respect to the setting mount 52e in relation to the center part of the rear panel 2, and a securing position of the securing screw 8d is located at the part outside with respect to the setting mount 52g in relation to the center part of the rear panel 2. In the supporting members 54a and 54b, diameters of four holes for inserting respective four screws 8a-8d are set larger than a diameter of four screws 8a-8d. For example, as shown in FIG. 3, a diameter of a hole 54bb for inserting the screw 8a is set larger than a diameter of the screw 8a. 
     As shown in FIG. 3, insulating washers 21 are provided between every two flat-shaped electrodes around the securing screws 8a. A metal-backed layer 22 is provided on the inner surface of the fluorescent screen 13. 
     In FIG. 1, the four tension plates 55a-55d and the four spring plates 56a-56d are made of the alloy, such as a stainless steel. The four tension plates 55a-55d and the four spring plates 56a-56d form resilient retaining means, and are disposed at four corners of supporting means, respectively. The four tension plates 55a-55d and the four spring plates 56a-56d hold four end parts of the securing members 53a and 53b, respectively. 
     An example of this resilient retaining means of the present invention will be elucidated with reference to FIG. 3 and FIG. 5. FIG. 5 is an enlarged view showing resilient retaining means of the present invention. 
     As shown in FIG. 3 and FIG. 5, the tension plate 55a comprises a first hook 55aa, a second hook 55ab, a hole 55ac and a protruding portion 55ad. The spring plate 56a has a hole 56aa. Each of the first hook 55aa and the second hook 5 serves as a stopper to limit deformations of the securing member 53a. That is, when the tension plate 55a is fixed to the setting mount 52a, each of the first hook 55aa and the second hook 55ab is disposed above the upper surface of the securing member 53a as shown in FIG. 3. If one end part of the securing member 53a is warped more than a predetermined degree by thermal deformation, the first hook 55aa and the second hook 55ab come in contact with one end part of the securing member 53a, respectively. As a result, deformations of the securing member 53a is limited to a predetermined degree. It is possible that the first hook 55aa and the second hook 55ab also limit deformations of the securing member 53a caused by external vibration and shock. 
     Apart from the aforementioned explanation, where the tension plate 55a has two hooks 55aa and 55ab as the stopper, an alternative construction may be such that the tension plate 55a has one hook, for example, the first hook 55aa only. 
     As shown in FIG. 3 and FIG. 5, the hole 55ac is formed in the tension plate 55a for welding the tension plate 55a to the setting mount 52a. Because this welding of the tension plate 55a is performed in the bottom parts of the hole 55ac as well as the welding of the securing member 53a, plural welding parts 58 do not protrude above a level of the surface of the tension plate 55a as shown in FIG. 3. 
     As shown in FIG. 3, the protruding portion 55ad is provided on one surface of the tension plate 55a so as to project toward the rear panel 2. This protruding portion 55ad is formed by pushing the other surface of the tension plate 55a. 
     As shown in FIG. 3 and FIG. 5, the spring plate 56a is fixed to a rear side of the securing member 53a so as to cover a predetermined part of the second hole 53ab. Because this welding of the spring plate 56a is performed in the bottom parts of the hole 55ac as well as the welding of the securing member 53a, plural welding parts 59 do not protrude above a level of the surface of the spring plate 56a as shown in FIG. 3. 
     When the tension plate 55a is fixed to the setting mount 52a, the protruding portion 55ad abuts on the spring plate 56a. Thereby, the spring plate 56a is pressed down toward the rear panel 2. Thus, the end part of the securing member 53a is elastically held by the tension plate 55a and the spring plate 56a. It is preferred that elasticity of the tension plate 55a is larger than that of the spring plate 56a. 
     Apart from the aforementioned explanation, where the spring plate 56a having elasticity is fixed to the securing member 53a by welding, an alternative construction may be such that the spring plate 56a and the securing member 53a are formed integrally, and the securing member 53a is held by the elasticity of the tension plate 55a. 
     As shown in FIG. 5, when the tension plate 55a is fixed to the setting mount 52a in the second hole 53ab, three gaps G1, G2 and G3 are formed at the part outside with respect to the tension plate 55a in relation to the center part of the rear panel 2 in the second hole 53ab. 
     In this embodiment, when the flat type image display apparatus 100 is heated, degrees of the thermal deformations are larger as the order advances from the rear panel 2 through the frame of the supporting unit 51 and to the flat-shaped electrode unit 7. Therefore, when the flat type image display apparatus 100 is heated, the tension plate 55a is moved toward the part outside in relation to the center part of the rear panel 2 by the deformation of the rear panel 2, such as shown by an arrow &#34;V&#34; shown in FIG. 5. As a result, the tension plate 55a absorbs a difference in degrees of thermal deformations between the rear panel 2, the flat-shaped electrode unit 7 and the frame of the supporting unit 51 eliminating from giving an undesirable stress to the flat-shaped electrode unit 7. 
     Sizes of L1, L2 and L3 of the gaps G1, G2 and G3 as shown in FIG. 3 are as follows: 
     
         L1=2 mm, L2=1 mm, L3=2 mm. 
    
     Furthermore, as has been elucidated in the above, the protruding portion 55ad of the tension plate 55a only abuts on the spring plate 56a. Therefore, when the tension plate 55a is moved with the tilt to the spring plate 56a, it is possible that the tension plate 55a smoothly tilts to the spring plate 56a. 
     In the aforementioned explanation, the tension plate 55a and the spring plate 56a, which are located at the upper-left side of FIG. 1, are described. Each of the tension plates 55b, 55c and 55d is configured the same as the tension plate 55a, and each of the spring plates 56b, 56c and 56d is configured as same as the spring plate 56a. That is, in FIG. 1, each of hooks 55ba, 55ca and 55da correspond to the first hook 55aa, and each of hooks 55bb, 55cb and 55db correspond to the second hook 55ab. Furthermore, each of holes 55bc, 55cc and 55dc correspond to the hole 55ac, and each of holes 56ba, 56ca and 56da correspond to the hole 56aa. A protruding portion (not shown) is provided on the tension plates 55b, 55c and 55d for abutting on the respective the spring plates 56b, 56c and 56d. Therefore, explanations of the tension plates 55b, 55c and 55d and the spring plates 56b, 56c and 56d are omitted. 
     As shown in FIG. 1, the spacer 57a is provided between the supporting member 54a and the setting mount 52d. The spacer 57a is fixed to the supporting member 54a and the setting mount 52d at a hole 57aa (FIG. 6) by welding. This welding method of the spacer 57a is as same as the welding method of the securing member 53a. Similarly, the spacer 57b is provided between the supporting member 54b and the setting mount 52h. The spacer 57b is fixed to the supporting member 54b and the setting mount 52h at a hole 57ba (FIG. 2) by welding. This welding method of the spacer 57b is as same as the welding method of the securing member 53a. 
     A function of the spacer 57a will be elucidated with reference to FIG. 6. FIG. 6 is a lateral view showing the supporting unit in accordance with the present invention. Because the spacer 57b is configured as same as the spacer 57a, the explanation of the spacer 57b applies as it is to the former, and hence its explanation is omitted. 
     As shown in FIG. 6, thickness of the spacer 57a is smaller than those of the securing members 53a and 53b. Furthermore, three setting mounts 52c, 52d and 52e are fixed to the rear panel 2 with a predetermined height from the rear panel 2. Accordingly, the height of the supporting member 54a from the rear panel 2, a height of the intermediate part is lower than the heights of both end parts. That is, the intermediate part of the supporting member 54a is fixed to the setting mount 52d via the spacer 57a so that a clearance 61 is formed between the intermediate part of the supporting member 54a and the flat-shaped electrode unit 7. For example, the clearance 61 is about 40 microns between the insulating film 20 and the flat-shaped electrode unit 7. 
     When the vacuum case is evacuated by the evacuation pipe 4, the rear panel 2 is deformed into the rear panel 2&#39; shown by dashed lines of FIG. 6. Thereby, the intermediate part of the supporting member 54a is pushed toward the flat-shaped electrode unit 7 via the setting mount 52d and the spacer 57a. However, since the clearance 61 is provided between the intermediate part of the supporting member 54a and the flat-shaped electrode unit 7, the intermediate part of the supporting member 54a does not come in contact with the flat-shaped electrode unit 7. Thus, the clearance 61 absorbs the deformation of the supporting member 54a eliminating from giving an undesirable stress to the flat-shaped electrode unit 7. 
     Apart from the aforementioned explanation, wherein the thickness of the spacer 57a is smaller than those of the securing members 53a and 53b, and the heights of the setting mounts 52c, 52d and 52e from the rear panel 2 are the same as each other, an alternative construction may be such that the height of the setting mount 52d from the rear panel 2 is lower than those of the setting mounts 52c and 52e without the spacer 57a. 
     With respect to the securing members 53a and 53b, the countermeasure against the evacuation of the vacuum case is not required. That is because, for example, as shown in FIG. 3, the securing member 53a is disposed under the supporting member 54b against the flat-shaped electrode unit 7. Thereby, when the vacuum case is evacuated by the evacuation pipe 4, the intermediate part of the securing member 53a does not come in contact with the flat-shaped electrode unit 7 after the intermediate part of the securing member 53a is pushed toward the flat-shaped electrode unit 7 via the setting mount 52b (FIG. 1). As has been elucidated in the above, the heat-resistant insulating frame 50a are only fitted to the securing member 53a at both ends of the heat-resistant insulating frame 50a. Therefore, when the vacuum case is evacuated by the evacuation pipe 4, the intermediate part of the heat-resistant insulating frame 50a does not push the flat-shaped electrode unit 7. As a result, the plural linear cathodes 10 does not receive an undesirable stress from the heat-resistant insulating frame 50a. 
     Thus, in the supporting unit 51 of the present invention, when the vacuum case is evacuated by the evacuation pipe 4, the flat-shaped electrode unit 7 and the plural linear cathodes 10 do not receive an undesirable stress. These functions against the flat-shaped electrode unit 7 and the plural linear cathodes 10 are effectively performed not only in deformations caused by the evacuation but also deformations caused by heat, the external vibrations and shocks. 
     Furthermore, the supporting unit 51 of the present invention has technical advantages as follows: 
     (1) Because the frame of the supporting unit 51 is of the same material as the flat-shaped electrode unit 7, a difference in degrees of thermal deformations between the frame of the supporting unit 51 and the flat-shaped electrode unit 7 is smaller than that of the prior art. As a result, the stress of the flat-shaped electrode unit 7 given from the distortion of the frame is substantially eliminated. 
     (2) As has been elucidated in the above, the four intermediate parts of the frame are fixed to the rear panel 2 via the respective setting mounts 52b, 52d, 52f and 52h, and the four corners of the frame are held by the resilient retaining means consisted of the tension plates 55a-55d and the spring plates 56a-56d. Therefore, the four corners of the frame make the largest displacement from the corresponding parts on the rear panel 2, the flat-shaped electrode unit 7 and the frame. As a result, it is possible that the resilient retaining means eliminates the largest difference given to the flat-shaped electrode unit 7 through moving of the tension plates 55a-55d in the respective holes 53ab, 53ac, 53bb and 53bc. Accordingly, it is possible to prevent generations of the cracks in the rear panel 2 and the bonding glass member 19 for fixing the setting mounts 52a-52h. 
     (3) The tension plates 55a, 55b, 55c and 55d are disposed in the holes 53ab, 53ac, 53bb and 53bc, respectively, so as to form three gaps G1, G2 and G3 in the respective holes 53ab, 53ac, 53bb and 53bc. Furthermore, the clearance 61 is provided between the flat-shaped electrode unit 7 and the supporting members 54a and 54b. Thereby, gaps G1, G2 and G3 and the clearance 61 can relieve defects caused by the size differences of the securing members 53a and 53b, as well as, that of the supporting members 54a and 54b and assembly of the supporting unit 51. Therefore, it is possible to assemble the supporting unit 51 easily. 
     Moreover, in this preferred embodiment, when peripheral parts of the front housing 1 are fixed to the rear panel 2 by the bonding glass member 3, the output terminals 6 are pulled toward the part outside of the vacuum case with a predetermined force. Concretely, for example, in FIG. 3, when peripheral parts of the front housing 1 is fixed to the rear panel 2 by the bonding glass member 3, a curve part 6b of the output terminal 6 is likely to be pulled toward a connecting part 6a of the output terminal 6 by the thermal deformation of the flat-shaped electrode 7b. In this preferred embodiment, when peripheral parts of the front housing 1 is fixed to the rear panel 2 by the bonding glass member 3, the output terminal 6 is pulled with a predetermined force in a direction of an arrow &#34;U&#34; of FIG. 3. As a result, it is possible to prevent the thermal deformation of the flat-shaped electrode 7b. 
     &lt;A MODIFIED VERSION OF THE PREFERRED EMBODIMENT&gt; 
     A modified version of the preferred embodiment will be elucidated with reference to FIG. 7, which is a front view of a modified version of the supporting unit in accordance with the preferred embodiment of the present invention. In this modified version, the same components and parts as those of the preferred embodiment are designated by the same numerals, and corresponding descriptions similarly apply. Therefore, the descriptions will be made mainly on the modified parts from the preferred embodiment. 
     In this modified version, the frame of the supporting unit 51 and the flat-shaped electrode unit 7 are made of a metal, such as Fe. Thereby, when the flat type image display apparatus 100 is heated, degrees of the thermal deformations are larger as the order advances from the frame of the supporting unit 51 through the flat-shaped electrode unit 7 and to the rear panel 2. 
     Accordingly, as shown in an upper-left side corner of FIG. 7, for example, when the tension plate 55a&#39; is fixed to the setting mount 52a in the second hole 55ab, the three gaps G1&#39;, G2&#39; and G3&#39; are formed at the part inside with respect to the tension plate 55a&#39; in relation to the center part of the rear panel 2 in the second hole 53ab. 
     When the flat type image display apparatus 100 is heated, the tension plate 55a&#39; is moved toward the part inside in relation to the center part of the rear panel 2. As a result, the tension plate 55a&#39; absorbs a difference in degrees of thermal deformations between the rear panel 2, the flat-shaped electrode unit 7 and the frame of the supporting unit 51 without giving an undesirable stress to the flat-shaped electrode unit 7. 
     Although the present invention has been described in terms of the presently preferred embodiment, it is to be understood that such disclosure is not to be interpreted as limiting. Various alternations and modifications will no doubt become apparent to those skilled in the art after having read the above disclosure. Accordingly, it is intended that the appended claims be interpreted as covering all alternations and modifications as fall within the true spirit and scope of the invention.