Bulb for color cathode ray tube and color cathode ray tube and methods for production thereof

Information

  • Patent Grant
  • 6682864
  • Patent Number
    6,682,864
  • Date Filed
    Wednesday, January 3, 2001
    23 years ago
  • Date Issued
    Tuesday, January 27, 2004
    20 years ago
Abstract
A bulb for a color cathode ray tube having a face plate and a color selection member having a plurality of opening portions, wherein X is a nominal diagonal dimension of the bulb, P is a pitch of the opening portions along an electron beam sweep direction in the central portion of the bulb, GH is a distance between an inner surface of the face plate and the color selection member in the central portion of the bulb, and LT is a value obtained by dividing a size of the opening portion along the electron beam sweep direction in the central portion of the bulb by the pitch P and the expressions0.0117X−0.0457
Description




BACKGROUND OF THE INVENTION AND RELATED ART STATEMENT




The present invention relates to a bulb for a color cathode ray tube and a color cathode ray tube, and also relates to methods for the production thereof.




For example, in a bulb for a color cathode ray tube having a color selection member of aperture grille type, generally, an inner surface of a face plate has, for example, stripe-shaped fluorescent material layers for red, green and blue and a black-matrix (stripe-shaped light absorption black layer) present between one of the fluorescent material layers and another. And, an electron gun is incorporated into the above bulb, and the inside of the bulb is vacuumed, whereby a color cathode ray tube is completed. The method of forming the above stripe-shaped color fluorescent layer will be explained with reference to schematic partial end views of the face plate, etc., shown in

FIGS. 47A

to


47


C and

FIGS. 48A and 48B

. The above stripe-shaped color fluorescent layer is formed by means of an opening portion, more specifically, by means of a face plate


11


to which a color selection member


13


of aperture grille type having stripe-shaped slits


14


extending in parallel with the perpendicular direction of the face plate


11


is attached.

FIG. 47B

alone shows the color selection member


13


.




First, a light sensitive film


20


is applied to the inner surface of the face plate


11


and dried (see FIG.


47


A), and then, a stripe-shaped exposed region


21


is formed in the light sensitive film


20


with an ultraviolet light which is emitted from an exposure light source (not shown) and passes through the stripe-shaped slit


14


formed in the color selection member


13


(see FIG.


47


B). For forming fluorescent material layers for red, green and blue, the above exposure is carried out three times by changing the exposure light source in position for each time. Then, the light sensitive film


20


is developed and selectively removed, to retain a remaining portion (exposed and developed light sensitive film)


22


on the inner surface of the face plate


11


(see FIG.


47


C). Then, a carbon agent is applied to the entire surface, and the remaining portion


22


of the light sensitive film and the carbon agent thereon are removed by a lift-off method, to form a stripe-shaped black-matrix


23


composed of the carbon agent (see FIG.


48


A). Then, fluorescent material layers


24


for red, green and blue are formed on the exposed inner surfaces of the face plate (portion


11


B of exposed inner surface of the face plate


11


, the portion


11


B being present between one black-matrix


23


and another black-matrix


23


) (see FIG.


48


B). Specifically, for example, a photosensitive fluorescent material slurry for red is applied to the entire surface, exposed to a light and developed, then, a photosensitive fluorescent material slurry for green is applied to the entire surface, exposed to a light and developed, and further, a photosensitive fluorescent material slurry for blue is applied, exposed to a light and developed.




In the above exposure method, an ultraviolet light emitted from one exposure light source is used. In some optical dimensions of a bulb for a color cathode ray tube, an exposure intensity of a transmitted light (exposure dosage on the light sensitive film


20


) of an ultraviolet light through the slit


14


which is an opening portion formed in the color selection member


13


, has a distribution of a Fresnel diffraction wave as is schematically shown in FIG.


52


A. The above Fresnel diffraction is known as near-field diffraction, and generally is obtained when an observation screen is located in a finite distance from a diffraction aperture. In the graph of the exposure intensity of the transmitted light in

FIG. 52A

, the axis of abscissas shows the horizontal direction of the face plate and the axis of ordinates show the exposure intensity of the transmitted light. Further, the origin is the center of the stripe-shaped exposed region of the light sensitive film.




When the above light sensitive film


20


is exposed to a light, developed and selectively removed, heavy convexo-concave shapes are formed in edge portions of the remaining portion


22


of the light sensitive film (see FIG.


52


B). The above phenomenon is caused by the formation of stripe-shaped edge portions of the exposed region


21


on the basis of an area of a transmitted-light strength in which area the derivative of the first order (∂I/∂x) of the transmitted-light strength on the light sensitive film


20


has an extremely small value. In the above expression, “I” stands for a transmitted-light intensity (in other words, exposure dosage on the light sensitive film


20


) and “x” stands for an electron beam sweep direction, specifically, the horizontal direction of the face plate


11


. If the derivative of the first order (∂I/∂x) of the transmitted-light strength on the light sensitive film


20


comes to be an extremely small value, the value of the derivative of the first order of crosslinking degree distribution of the light sensitive film


20


comes to be small (that is, the crosslinking degree distribution of the light sensitive film


20


in the horizontal direction of the face plate


11


loses steepness), so that the heavy convexo-concave shapes are formed in the edge portions of the remaining portion


22


of the light sensitive film. As a result, the edge portions of the stripe-shaped fluorescent material layer


24


cause heavy convexo-concave shapes, macroscopically, an image display non-uniformity is caused in a color cathode ray tube, and the color cathode ray tube is extremely deteriorated in quality.




JP-A-60-84738 discloses a method for avoiding the above phenomenon. In the method disclosed in the above Laid-Open publication, a plurality of exposure light sources are arranged in different positions along the horizontal direction of the face plate, and a light sensitive film formed on an inner surface of a face plate is exposed to a predetermined stripe width using a transmitted-light strength distribution of superposed Fresnel diffraction waves. And, a correction lens system for correcting Fresnel diffraction conditions of each is selected depending upon an exposure light in the position of each exposure light source, and a plurality of exposure lights emitted from a plurality of the exposure light sources are adjusted such that Fresnel diffraction waves are superposed on the light sensitive film through the correction lens system and the color selection member for one stripe having a predetermined width. Further, a plurality of the exposure lights are adjusted such that the transmitted-light strength distribution is nearly constant on the entire surface of the light sensitive film formed on the inner surface of the face plate, and further that exposure is effected in a state where a differential value (∂i/∂x) of the transmitted-light strength distribution on a position corresponding to the edge of the stripe width is a value near a peak of the distribution of the differential value (∂i/∂x) or a value that has a certain level sufficient for preventing an edge non-uniformity of the stripe width.




The method disclosed in the above Laid-Open publication is effective for preventing the heavy convexo-concave shapes which occur in the edges of the remaining portion of the light sensitive film. It is remarkably suitable for producing a so-called commercial color cathode ray tube in which slits of a color selection member in a central portion of a bulb for a color cathode ray tube have a rough pitch or a color cathode ray tube for a computer display in which slits have a fine pitch. However, slits of a color selection member in a central portion of a bulb for a color cathode ray tube for digital broadcasting have a semi-fine pitch, and the semi-fine pitch is in an intermediate range between the pitch of slits of the color selection member in the commercial color cathode ray tube and the pitch of slits of the color selection member in the high-resolution color cathode ray tube for the computer display.




It has been found that even if the method disclosed in JP-A-60-84738 is employed for a color cathode ray tube in which the pitch of slits of the color selection member is in an intermediate range as described above, the heavy convexo-concave shapes are formed in edges of part of the light sensitive film remaining after exposure and development. As a result, the heavy convexo-concave shapes are formed in the edge portions of the stripe-shaped fluorescent material layer, and macroscopically, image display non-uniformity is caused in part of the color cathode ray tube, so that the color cathode ray tube is downgraded in quality to a great extent.




OBJECT AND SUMMARY OF THE INVENTION




Therefore, concerning a color cathode ray tube in which the pitch of the opening portions formed in a color selection member is in an intermediate range between the pitch of the opening portions formed in the color selection member in a commercial color cathode ray tube and the pitch of the opening portions formed in the color selection member in a high-resolution color cathode ray tube for a computer display, it is therefore an object of the present invention to provide a color cathode ray tube which permits the prevention of formation of convexo-concave shapes in edge portions of a fluorescent material layer, a bulb for such a color cathode ray tube and methods for the production thereof.




The method for producing a bulb for a color cathode ray tube, provided by the present invention, is a method for producing a bulb for a color cathode ray tube, said bulb comprising a face plate and a color selection member having a plurality of opening portions, and satisfying the following expression (1), wherein X is a nominal diagonal inchage of the bulb and P (unit: mm) is a pitch of the opening portions along an electron beam sweep direction in the central portion of the bulb.




Further, the method for producing a color cathode ray tube, provided by the present invention, is a method for producing a color cathode ray tube constituted of a bulb for a color cathode ray tube, said bulb comprising a face plate and a color selection member having a plurality of opening portions, and said bulb satisfying the following expression (1), wherein X is a nominal diagonal inchage of the bulb and P (unit: mm) is a pitch of the opening portions along an electron beam sweep direction in the central portion of the bulb.




In a circumferential portion of the face plate along the electron beam sweep direction, it is not necessary to satisfy the following expression (1).






0.0117


X


−0.0457


<P<


0.018


X


−0.0771  (1)






The above methods includes the step of exposing a light, sensitive film formed on an inner surface of the face plate on the basis of a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which are emitted from a plurality of exposure light sources arranged in different positions along the electron beam sweep direction and pass through the opening portions formed in the color selection member, to form exposed regions in the light sensitive film which regions correspond to the opening portions,




in which a transmitted-light strength of superposed Fresnel diffraction waves of the two exposure lights (to be sometimes referred to as “superposed transmitted-light strength” hereinafter), out of a plurality of the exposure lights, which are emitted from the two exposure light sources contributing to the exposure of edge portions of the light sensitive film corresponding to each opening portion satisfies the following requirements (A) and (B);




(A) in an area of the superposed transmitted-light strength in which area the superposed transmitted-light strength on the light sensitive film decreases along the electron beam sweep direction (x direction) from a central portion of the exposed region of the light sensitive film corresponding to each opening portion, the derivative of the first order (∂i/∂x) of the superposed transmitted-light strength has at least one upward-convex area, and




(B) the edge portions of the exposed light sensitive film corresponding to each opening portion are included in an area of the superposed transmitted-light strength which area corresponds to the upward-convex area which appears first along the electron beam sweep direction (x direction) from the central portion of the exposed region corresponding to each opening portion, out of the upward-convex areas of the derivative of the first order (∂i/∂x) of the superposed transmitted-light strength.




The above “two exposure lights which are emitted from the two exposure light sources contributing to the exposure of edge portions of the light sensitive film corresponding to each opening portion” means the following. When the exposure light sources are individually operated to expose the light sensitive film formed on the inner surface of the face plate, each of the above exposure lights is an exposure light which satisfies I


MIN


≦I


1


wherein I


1


is a transmitted-light strength in the edge portion of the light sensitive film corresponding to each opening portion and I


MIN


is a lowest transmitted-light strength required for exposure of the light sensitive film.




Of upward-convex areas of the derivative of the first order (∂I/∂x) of the above superposed transmitted-light strength, the upward-convex area which appears first along the electron beam sweep direction from the central portion of the exposed region will be referred to as a first wave, and the upward-convex area which appears thereafter will be referred to as a second wave, for the convenience.




In the method for producing a bulb for a color cathode ray tube or the method for producing a color cathode ray tube, provided by the present invention (these methods will be sometimes generally referred to as “method of the present invention” hereinafter), preferably, the following expression (2) is satisfied. In the expression (2), GH (unit: mm) is a distance between the inner surface of the face plate and the color selection member in the central portion of the bulb and LT (corresponding to a so-called opening rate) is a value obtained by dividing a size (unit: mm) of the opening portion along the electron beam sweep direction in the central portion of the bulb by the pitch P (unit: mm). In a circumferential portion of the face plate along the electron beam sweep direction, it is not required to satisfy the following expression (2).






2.8×10


−2




<P×LT×GH




−½


<4.1×10


−2


  (2)






After the formation of the exposed regions in the light sensitive film formed on the inner surface of the face plate which regions correspond to the openings, the method of the present invention may further includes the steps of selectively removing the light sensitive film by development, forming a light-absorption layer (for example, black-matrix) on the exposed inner surface of the face plate and removing the remaining portion of the light sensitive film, and then, forming a fluorescent material layer on the exposed inner surface of the face plate. For reliably forming the exposed regions having a proper size, preferably, a correction lens system is disposed between the exposure light sources and the color selection member. In the method for producing a bulb for a color cathode ray tube, provided by the present invention, the face plate and a funnel, etc., are assembled to complete the bulb for a color cathode ray tube. In the method for producing a color cathode ray tube, provided by the present invention, an electron gun is incorporated into the obtained bulb for a color cathode ray tube, and the inside of the bulb is vacuumed, to complete the color cathode ray tube.




The method of the present invention may employ a constitution in which the number of the exposure light sources is 2. In this case, the two exposure light sources correspond to “the two exposure light sources contributing to the exposure of edge portions of the light sensitive film corresponding to each opening portion”. There may be also employed a constitution in which the number of the exposure light sources is 3 or more and the transmitted-light strength of superposed Fresnel diffraction waves of the exposure lights from all of the exposure light sources satisfies I


CENTER


/I


EDGE


≧1.2, wherein I


CENTER


is a transmitted-light strength in the central portion of the exposed region corresponding to each opening portion and IEDGE is a transmitted-light strength in the edge portion of the light sensitive film corresponding to each opening portion. In the above constitution, reliable exposure is secured particularly in the central portion of the light sensitive film corresponding to each opening portion. In this case, two exposure light sources out of the three or more exposure light sources correspond to “the two exposure light sources contributing to the exposure of edge portions of the light sensitive film corresponding to each opening portion”, and the remaining exposure light source or sources contribute, for example, to the exposure of the central portion of the exposed region corresponding to each opening portion. When three or more exposure light sources are used, preferably, the remaining exposure light source or sources (to be sometimes referred to as “exposure light source for exposing a central portion” hereinafter) are disposed between the two exposure light sources contributing to the edge portion of the light sensitive film corresponding to each opening portion (to be sometimes referred to as “exposure light source for exposing an edge portion” hereinafter). However, the light source or sources for exposing a central portion may be disposed outside the two exposure light sources for exposing an edge portion. Further, when four or more exposure light sources are used, preferably, the exposure light sources for exposing a central portion are disposed between the two exposure light sources for exposing an edge portion. Alternatively, the exposure light sources for exposing a central portion may be disposed outside the two exposure light sources for exposing an edge portion, or the exposure light sources for exposing a central portion may be disposed between and outside the two exposure light sources for exposing an edge portion. Each exposure light source may be constituted, for example, of an ultraviolet light source.




The bulb for a color cathode ray tube provided by the present invention for achieving the above object is a bulb comprising a face plate and a color selection member having a plurality of opening portions.




The color cathode ray tube of the present invention for achieving the above object is a color cathode ray tube constituted of a bulb for a cathode ray tube, said bulb comprising a face plate and a color selection member having a plurality of opening portions.




The bulb for a color cathode ray tube or the color cathode ray tube provided by the present invention satisfies the following expressions (1) and (2), wherein X is a nominal diagonal inchage of the bulb, P (unit: mm) is a pitch of the opening portions along an electron beam sweep direction in the central portion of the bulb, GH (unit: mm) is a distance between an inner surface of the face plate and the color selection member in the central portion of the bulb, and LT (corresponding to a so-called opening rate) is a value obtained by dividing a size (unit: mm) of the opening portion along the electron beam sweep direction in the central portion of the bulb by the pitch P (unit: mm).






0.0117


X


−0.0457<


P


<0.018


X


−0.0771  (1)








2.8×10


−2




<P×LT×GH




−½


<4.1×10


−2


  (2)






In a circumferential portion of the face place along the electron beam sweep direction, it is not required to satisfy the above expressions (1) and (2).




The pitch of the opening portions may be constant toward the circumferential portion of the face plate along the electron beam sweep direction. Alternatively, the above pitch may be broadened toward the circumferential portion along the electron beam sweep direction, whereby the color purity in the circumferential portion of the color cathode ray tube can be improved to a great extent. The size of the opening portions may be constant toward the circumferential portion along the electron beam sweep direction or may be broadened toward the circumferential portion along the electron beam sweep direction.




The edge portion of the exposed light sensitive film is included in the area of the superposed transmitted-light strength which area corresponds to the first wave of the derivative of the first order (∂I/∂x). However, it is not much desirable that the edge portion of the exposed light sensitive film is included in the area of the superposed transmitted-light strength which area corresponds to the first wave near a transition area from the first wave to the second wave of the derivative of the first order (∂I/∂x). Therefore, preferably, the following α, β and γ satisfy the following expression (3), wherein α is a peak value of the first wave of the derivative of the first order (∂I/∂x), β is a value of the derivative of the first order (∂i/∂x) in the transition area from the first wave to the second wave, and γ is a value of the derivative of the first order (∂i/∂x) in the area (portion) of the superposed transmitted-light strength in which the edge portion of the exposed light sensitive film is included.






γ≧β+0.1(α−β)  (3)







FIGS. 49A and 49B

show layouts of the color selection member and the fluorescent material layers when the color selection member is of aperture grille type.

FIG. 49A

also shows the pitch P of the opening portions along the electron beam sweep direction in the central portion of the bulb. In the color selection member of aperture grille type, a plurality of slits corresponding to the opening portions are arranged in parallel. The pitch P corresponds to a distance from the center of one slit to the center of a neighboring slit.





FIGS. 50A and 50B

show layouts of the color selection member and the fluorescent material layers when the color selection member is of dot-type shadow mask type.

FIG. 50A

also shows the pitch P of the opening portions along the electron beam sweep direction in the central portion of the bulb. In the color selection member of dot-type shadow mask type, a plurality of circular through holes corresponding to the opening portions are arranged in apexes of triangles. The pitch P corresponds to a distance from the center of one through hole to the center of a neighboring through hole along the electron beam sweep direction.





FIGS. 51A and 51B

show layouts of the color selection member and the fluorescent material layers when the color selection member is of slot-type shadow mask type.

FIG. 51A

also shows the pitch P of the opening portions along the electron beam sweep direction in the central portion of the bulb. In the color selection member of slot-type shadow mask type, a plurality of short slits corresponding to the opening portions are arranged in one direction (at right angles with the electron beam sweep direction), and these slits are arranged in parallel with one another. The pitch P corresponds to a distance from the center of one short slot to the center of a neighboring short slot along the electron beam sweep direction.




In

FIGS. 49B

,


50


B and


51


B, symbols “R”, “G” and “B” stand for a fluorescent material layer for emitting a light in red, a fluorescent material layer for emitting a light in green and a fluorescent material layer for emitting a light in blue, respectively. In

FIGS. 49A and 49B

, the opening portions and the fluorescent material layers are provided with slanting lines for clarification thereof.




The face plate may have a lateral dimension:vertical dimension ratio of nominal 16:9 or 4:3. Although not specially limited, the structure of the face plate includes a structure in which the outer surface of effective screen field of the face plate may be spherical or curved, a structure in which the outer surface of the effective screen field of the face plate is substantially flat and the thickness of the circumferential portions of the effective screen filed in the horizontal direction is larger than the thickness of the central portion of the effective screen field, and a structure in which the face plate in the effective screen field has a substantially uniform thickness. The structure of the color cathode ray tube includes a structure having a bulb for a color cathode ray tube in which the outer surface of the effective screen field of the face plate is substantially flat and a color selection member which is disposed to face the inner surface of the face plate inside the bulb and has a convex curvature toward the face plate. In this case, there may be employed a constitution in which the inner surface of the face plate has a concave curvature toward the color selection member and the curvature of the color selection member is greater than the curvature of the inner surface of the face plate or a constitution in which the inner surface of the face plate has a concave curvature toward the color selection member and the curvature of the color selection member is nearly equal to the curvature of the inner surface of the face plate. However, the above members shall not be limited to the above structures or constitutions. The above effective screen field refers to a face plate region where images are actually displayed when the bulb is incorporated into the color cathode ray tube. That the effective screen field of the face plate is substantially flat means that the effective screen field is flat within the production tolerance of the face plate. For example, in the face plate for a 28-inch bulb in which X=28, the production tolerance is approximately 1 to 2 mm or less. In the above case, the effective screen field appears to be substantially completely flat when visually observed. Further, a change in the thickness of the effective screen field from the central portion of the effective screen field to the circumferential portions in the horizontal direction can be expressed by an arc or a multinomial. When it is assumed that the bulb for a color cathode ray tube is held in a horizontal position and that the face plate is cut with a vertical plane, the curve drawn by the inner surface of the face plate may be a straight line, an arc, or a curve expressed by a multinomial. If the circumferential portions of the effective screen field in the horizontal direction has a thickness T and if the central portion of the effective screen field has a thickness of To, preferably, T=1.2T


0


to 1.3T


0


. The curvature of the inner surface of the face plate and the curvature of the color selection member refer to average values of curvatures of curves drawn by the cross section of the inner surface of the face plate and the cross section of the color selection member when it is assumed that the bulb is held in a horizontal position and that the face plate and the color selection member are cut with a horizontal plane. The above curves are preferably of an arc. In these cases, the curvature of the inner surface of the face plate and the curvature of the color selection member correspond to reciprocals of radii of the above arcs.




The material for constituting the light sensitive film includes, for example, PVP (polyvinyl pyrrolidone) and PVA (polyvinyl alcohol).




In designing the bulb for a color cathode ray tube or the color cathode ray tube, parameters such as the pitch of the opening portions and the size of the opening portions can be determined with a freedom to some extent although a certain limitation is imposed thereon. In the method of the present invention, the above expression (1) is satisfied and the edge portions of the exposed light sensitive film are included in the area of the superposed transmitted-light strength which area corresponds to the first wave in the derivative of the first order of the superposed transmitted-light strength, so that the edge portions of the light sensitive film remaining after exposure and development have no convexo-concave shapes. In the bulb for a color cathode ray tube or the color cathode ray tube provided by the present invention, the above expressions (1) and (2) are satisfied, so that the edge portions of the fluorescent material layer have no convexo-concave shapes.











BRIEF DESCRIPTION OF THE DRAWINGS




The present invention will be explained on the basis of Examples with reference to drawings hereinafter.





FIG. 1

is a conceptual view of an exposure apparatus suitable for practicing the method of Example 1 of the present invention.





FIG. 2

is an enlarged schematic partial cross-sectional view of a face plate, a color selection member, etc., in Example 1 of the present invention.





FIG. 3

is a schematic drawing of a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through one slit in Example 1 of the present invention.





FIG. 4

is a conceptual view of an exposure apparatus suitable for practicing the method of Example 2 of the present invention.





FIG. 5

is an enlarged schematic partial cross-sectional view of a face plate, a color selection member, etc., in Example 2 of the present invention.





FIG. 6

is a schematic drawing of a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through one slit in Example 2 of the present invention.





FIG. 7

is a graph of relational expression (1) of a nominal diagonal inchage X of a bulb for a color cathode ray tube and a pitch P of opening portions of a color selection member in the central portion of a bulb for a color cathode ray tube.





FIG. 8

is a graph of relational expression (2′) of a distance GH between an inner surface of a face plate in the central portion of a bulb for a color cathode ray tube and a color selection member, a value of LT obtained by dividing the size of an opening portion (width of a slit) in the central portion of the bulb for a color cathode ray tube by the pitch P of the color selection member and the pitch P of the color selection member.





FIG. 9

is schematic partial exploded drawing of a bulb for a color cathode ray tube.





FIGS. 10A and 10B

are a schematic perspective view of a color selection member of aperture grille type and an enlarged view of part of the color selection member, respectively.





FIG. 11

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (0,211) in the bulb for a color cathode ray tube in Example 1 of the present invention and a derivative of the first order (∂I/∂x) thereof.





FIG. 12

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (0,0) in the bulb for a color cathode ray tube in Example 1 of the present invention and a derivative of the first order (∂i/∂x) thereof.





FIG. 13

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (128,211) in the bulb for a color cathode ray tube in Example 1 of the present invention and a derivative of the first order (∂i/∂x) thereof.





FIG. 14

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (128,0) in the bulb for a color cathode ray tube in Example 1 of the present invention and a derivative of the first order (∂I/∂x) thereof.





FIG. 15

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (375,211) in the bulb for a color cathode ray tube in Example 1 of the present invention and a derivative of the first order (∂I/∂x) thereof.





FIG. 16

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (375,0) in the bulb for a color cathode ray tube in Example


1


of the present invention and a derivative of the first order (∂I/∂x) thereof.





FIG. 17

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (0,211) in the bulb for a color cathode ray tube in Example 2 of the present invention and a derivative of the first order (∂I/∂x) thereof.





FIG. 18

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (0,0) in the bulb for a color cathode ray tube in Example 2 of the present invention and a derivative of the first order (∂I/∂x) thereof.





FIG. 19

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (128,211) in the bulb for a color cathode ray tube in Example 2 of the present invention and a derivative of the first order (∂I/∂x) thereof.





FIG. 20

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (128,0) in the bulb for a color cathode ray tube in Example 2 of the present invention and a derivative of the first order (∂I/∂x) thereof.





FIG. 21

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (375,211) in the bulb for a color cathode ray tube in Example 2 of the present invention and a derivative of the first order (∂I/∂x) thereof.





FIG. 22

is a graph showing a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (375,0) in the bulb for a color cathode ray tube in Example 2 of the present invention and a derivative of the first order (∂I/∂x) thereof.





FIG. 23

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (0,198) in the bulb for a color cathode ray tube in Comparative Example 1 and a derivative of the first order (∂i/∂x) thereof.





FIG. 24

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (0,0) in the bulb for a color cathode ray tube in Comparative Example 1 and a derivative of the first order (∂I/∂x) thereof.





FIG. 25

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (192,198) in the bulb for a color cathode ray tube in Comparative Example 1 and a derivative of the first order (∂I/∂x) thereof.





FIG. 26

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (192,0) in the bulb for a color cathode ray tube in Comparative Example 1 and a derivative of the first order (∂I/∂x) thereof.





FIG. 27

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (375,198) in the bulb for a color cathode ray tube in Comparative Example 1 and a derivative of the first order (∂I/∂x) thereof.





FIG. 28

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (375,0) in the bulb for a color cathode ray tube in Comparative Example 1 and a derivative of the first order (∂I/∂x) thereof.





FIG. 29

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (0,198) in the bulb for a color cathode ray tube in Comparative Example 2 and a derivative of the first order (∂I/∂x) thereof.





FIG. 30

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (0,0) in the bulb for a color cathode ray tube in Comparative Example 2 and a derivative of the first order (∂I/∂x) thereof.





FIG. 31

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (128,198) in the bulb for a color cathode ray tube in Comparative Example 2 and a derivative of the first order (∂I/∂x) thereof.





FIG. 32

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (128,0) in the bulb for a color cathode ray tube in Comparative Example 2 and a derivative of the first order (∂I/∂x) thereof.





FIG. 33

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (375,198) in the bulb for a color cathode ray tube in Comparative Example 2 and a derivative of the first order (∂I/∂x) thereof.





FIG. 34

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (375,0) in the bulb for a color cathode ray tube in Comparative Example 2 and a derivative of the first order (∂I/∂x) thereof.





FIG. 35

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (0,198) in the bulb for a color cathode ray tube in Comparative Example 3 and a derivative of the first order (∂I/∂x) thereof.





FIG. 36

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (0,0) in the bulb for a color cathode ray tube in Comparative Example 3 and a derivative of the first order (∂I/∂x) thereof.





FIG. 37

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (128,198) in the bulb for a color cathode ray tube in Comparative Example 3 and a derivative of the first order (∂I/∂x) thereof.





FIG. 38

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (128,0) in the bulb for a color cathode ray tube in Comparative Example 3 and a derivative of the first order (∂I/∂x) thereof.





FIG. 39

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (375,198) in the bulb for a color cathode ray tube in Comparative Example 3 and a derivative of the first order (∂I/∂x) thereof.





FIG. 40

is a graph showing a transmitted-light strength distribution of Fresnel diffraction waves of exposure lights which pass through a slit in a coordinate of (375,0) in the bulb for a color cathode ray tube in Comparative Example 3 and a derivative of the first order (∂I/∂x) thereof.





FIG. 41

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (0,211) in the bulb for a color cathode ray tube in Comparative Example 4 and a derivative of the first order (∂I/∂x) thereof.





FIG. 42

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (0,0) in the bulb for a color cathode ray tube in Comparative Example 4 and a derivative of the first order (∂I/∂x) thereof.





FIG. 43

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (128,211) in the bulb for a color cathode ray tube in Comparative Example 4 and a derivative of the first order (∂I/∂x) thereof.





FIG. 44

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (128,0) in the bulb for a color cathode ray tube in Comparative Example 4 and a derivative of the first order (∂I/∂x) thereof.





FIG. 45

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (375,211) in the bulb for a color cathode ray tube in Comparative Example 4 and a derivative of the first order (∂I/∂x) thereof.





FIG. 46

is a graph showing a transmitted-light strength distribution of Fresnel diffraction wave of exposure light which passes through a slit in a coordinate of (375,0) in the bulb for a color cathode ray tube in Comparative Example 4 and a derivative of the first order (∂I/∂x) thereof.





FIGS. 47A

,


47


B and


47


C are schematic partial end views of a face plate, etc., for explaining the steps of producing a bulb for a color cathode ray tube.





FIGS. 48A and 48B

, following

FIG. 47C

, are schematic partial end views of the face plate, etc., for explaining the steps of producing the bulb for a color cathode ray tube.





FIGS. 49A and 49B

are layouts of a color selection member and fluorescent material layers when the color selection member is of aperture grille type.





FIGS. 50A and 50B

are layouts of a color selection member and fluorescent material layers when the color selection member is of dot-type shadow mask type.





FIGS. 51A and 51B

are layouts of a color selection member and fluorescent material layers when the color selection member is of slot-type shadow mask type.





FIGS. 52A and 52B

are schematic drawings of a distribution of a Fresnel diffraction wave of an exposure light emitted from one exposure light source and a state where heavy convexo-concave shapes are caused in edge portions of a light sensitive film remaining on a face plate.





FIGS. 53A and 53B

are schematic partial cross-sectional views of a light sensitive film remaining on a face plate, for explaining a problem caused when two exposure light sources are used.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




EXAMPLE 1




A bulb


10


for a color cathode ray tube in Example 1 comprises a face plate


11


and a color selection member


13


of aperture grille type having stripe-shaped slits


14


(corresponding to a plurality of the opening portions) extending in parallel with the vertical direction (y-direction) of the face plate


11


. The basic structure of the bulb


10


in Example 1 is the same as the structure of a conventional bulb for a color cathode ray tube. The color cathode ray tube of Example 1 is constituted of the bulb for a color cathode ray tube in Example 1 and has an electron gun, and the basic structure thereof is the same as the structure of a conventional color cathode ray tube.




The face plate


11


is bonded to a funnel


12


with a glass-containing adhesive as shown in a partially cut drawing of the bulb


10


in

FIG. 9. A

tension band


17


is wound around the face plate


11


in the vicinity of the funnel


12


to increase the strength of the bulb


10


. As shown in a schematic perspective view of

FIG. 10A

, the color selection member


13


of aperture grille type is attached to a frame member


15


by a resistance welding method or a laser welding method in a state where a tension is applied thereto in the y-direction. The frame member


15


is removably attached to the face plate


11


with an attaching tool


16


made of a spring. As shown in

FIG. 10B

, the color selection member


13


has slits


14


corresponding to the opening portions.





FIG. 2

is an enlarged schematic partial cross-sectional view of some constituent elements of the bulb


10


such as the face plate


11


, the color selection member


13


, etc. The bulb or the color cathode ray tube in Example 1 satisfies the following expressions (1) and (2), wherein X is a nominal diagonal inchage of the bulb


10


, P (unit: mm) is a pitch of the opening portions along an electron beam sweep direction (x-direction) in the central portion of the bulb


10


(more specifically, a pitch of the slits


14


), GH (unit: mm) is a distance between an inner surface


11


A of the face plate


11


and the color selection member


13


in the central portion of the bulb


10


, and LT (corresponding to an opening rate) is a value obtained by dividing a size of the opening portion (specifically, the width of the slit


14


) (unit: mm) along the electron beam sweep direction in the central portion of the bulb


10


by the pitch P (more specifically, the pitch of the slits


14


). In Example 1, specifically, the value of P×LT×GH


−½


was determined to be 3.4×10


−2


.






0.0117


X


−0.0457<


P


<0.018


X


−0.0771  (1)








2.8×10


−2




<P×LT×GH




−1/2


<4.1×10


−2


  (2)






In

FIG. 7

, a region surrounded by the two straight lines corresponds to a region expressed by the expression (1). In

FIG. 7

, the axis of abscissas is the nominal diagonal inchage (X) of the bulb


10


, and the axis of ordinates is the pitch (P) of the slits


14


. A graph shown in

FIG. 8

is a graph obtained by modifying the expression (2) to the following expression (2′), and a region surrounded by the two curves is a region expressed by the expression (2′). In

FIG. 8

, the axis of abscissas is (P×LT), and the axis of ordinates is GH


−1/2


. A function expressed by the curve (sequence 1) formed by combining black circles is expressed by the following expression (2′-1), and a function expressed by the curve (sequence 2) formed by combining black squares is expressed by the following expression (2′-2).






2.8×10


−2


/(


P×LT


)<


GH




−1/2


<4.1×10


−2


/(


P×LT)


  (2′)










GH




−1/2


=4.1×10


−2


/(


P×LT


)  (2′-1)










GH




−1/2


=2.8×10


−2


/(


P×LT


)  (2′-2)






The bulb or the color cathode ray tube in Example 1 can be produced by the step of exposing a light sensitive film


20


formed on the inner surface


11


A of the face plate


11


on the basis of a transmitted-light strength distribution (corresponding to a superposed transmitted-light strength in Example 1) of superposed Fresnel diffraction waves of exposure lights which are emitted from a plurality of exposure light sources arranged in different positions along the electron beam sweep direction (specifically, the horizontal direction of the face plate


11


) and pass through the opening portions (slits


14


) formed in the color selection member


13


, to form exposed regions (more specifically, stripe-shaped exposed regions) in the light sensitive film


20


which regions correspond to the opening portions (slits


14


), so long as the expressions (1) and (2) are satisfied.




The method for producing the bulb in Example 1 is a method for producing a bulb for a color cathode ray tube which bulb comprises the face plate


11


and the color selection member


13


of aperture grille type having stripe-shaped slits


14


(corresponding a plurality of opening portions) extending in parallel with the vertical direction (y-direction) of the face plate


11


and satisfies the above expression (1) in which X is a nominal diagonal inchage of the bulb and P (unit: mm) is the pitch of the opening portions (more specifically, the pitch of the slits


14


) along the electron beam sweep direction (x-direction) in the central portion of the bulb


10


. The method for producing a color cathode ray tube in Example 1 is a method for producing a color cathode ray tube constituted of the above bulb.




In practicing the method for producing the bulb or the color cathode ray tube in Example 1 (to be generally referred to as “production method of Example 1” hereinafter), there is used a plurality of exposure light sources


31


(two ultraviolet light sources in Example 1) which are disposed in different positions along the horizontal direction (x-direction) of the face plate which direction is the electron beam sweep direction, as shown in the conceptual drawing of an exposure apparatus in FIG.


1


. Further, a correction lens system is disposed between the exposure light sources


31


and the color selection member


13


. The correction lens system comprises an illumination correction filter


32


, first correction lenses


33


A and


33


B and a second correction lens group


34


which are positioned in this order from the exposure light sources


31


side. The illumination correction filter


32


serves to optimize the size (width) of the fluorescent material layers to be obtained on the entire surface of the face plate


11


. The second correction lenses group


34


made of glass serves to approximate the paths of the exposure lights during the exposure to the paths of actual electron beams.




Further, when the first correction lenses


33


A and


33


B made of glass are provided, there can be attained a large value of the derivative of the first order (∂I/∂x) of the transmitted-light strength in the edge portion of the exposed stripe-shaped light sensitive film all over the inner surface of the face plate


11


, and the edge portions of the exposed stripe-shaped light sensitive film can be included in an area of the transmitted-light strength corresponding to the first wave of the derivative of the first order (∂I/∂x). When the light sensitive film is exposed to a light from one exposure light source


31


, the first correction lens


33


A is used, and when the light sensitive film is exposed to a light from the other exposure light source


31


, the first correction lens


33


B is used. The first correction lens


33


A and the first correction lens


33


B have identical characteristics (but symmetrical characteristic with regard to a z-axis shown in FIG.


1


). Each of the first correction lenses


33


A and


33


B has a smooth convexo-concave shape formed on one surface.




Specifically, the first correction lenses


33


A and


33


B for correcting Fresnel diffraction conditions are selected depending upon the exposure light sources used. In the exposure apparatus, a plurality of the exposure lights emitted from a plurality of the exposure light sources are adjusted such that their Fresnel diffraction waves are superposed on the light sensitive film


20


through the correction lens system


32


,


33


A,


33


B,


34


and the color selection member


13


so that the light sensitive film


20


is exposed in the form of stripes having a predetermined width depending upon the slits corresponding to the opening portions. Further, a plurality of the exposure lights are adjusted such that the value of the derivative of the first order (∂I/∂x) of the transmitted-light strength corresponding to the edge portions of the exposed stripe-shaped light sensitive film comes to be a value of a certain level or higher.




In the production method of Example 1, the face plate


11


having the inner surface


11


A on which the light sensitive film


20


is formed (applied) is prepared (see FIG.


47


A). The light sensitive film


20


formed (applied) on the inner surface


11


A of the face plate


11


is exposed to the exposure lights (see

FIGS. 1 and 2

) to form stripe-shaped exposed regions


21


in the light sensitive film


20


corresponding to the slits (see

FIG. 47B

) on the basis of the transmitted-light strength distribution of superposed Fresnel diffraction waves of the exposure lights which are emitted from a plurality of the exposure light sources


31


(two exposure light sources in Example 1) arranged in different positions along the horizontal direction of the face plate (x-direction), the electron beam sweep direction, and which pass through the slits


14


corresponding to the opening portions formed in the color selection member


13


.

FIG. 3

schematically shows, by a solid line, one example of each transmitted-light strength distribution of a Fresnel diffraction wave of each of the two exposure lights which pass through one slit


14


. A convexo-convex curved portion shown by a dotted line indicates a portion of a transmitted-light strength distribution in which portion the two exposure lights are superposed, that is, part of the transmitted-light strength distribution of superposed Fresnel diffraction waves of the two exposure lights.





FIGS. 11

,


12


,


13


,


14


,


15


and


16


show results of measurement of transmitted-light strength distributions of superposed Fresnel diffraction waves of the two exposure lights which pass through the slits


14


in coordinates (0,211), (0,0), (128,211), (128,0), (375,211) and (375,0) where the nominal diagonal inchage X of the bulb


10


is


36


(X=36), the center of the face plate


11


is an origin, a straight line extending in the horizontal direction (x-direction) of the face plate and passing through the origin is an x-axis and a straight line extending in the vertical direction (y-direction) of the face plate and passing through the origin is a y-axis. The unit of values in the coordinates is “mm”. In each drawing, the derivative of the first order (∂I/∂x) of the transmitted-light strength is shown by a dotted line. In

FIGS. 11

to


16


and

FIGS. 17

to


46


to be discussed later, the axis of abscissas shows a distance (unit: μm) from the center of the stripe-shaped exposed region of the light sensitive film, and the axis of ordinates shows relative values of the transmitted-light strength and the derivative of the first order (∂I/∂x) thereof. A chain line in parallel with the axis of ordinates shows a position corresponding to the edge portion of the exposed stripe-shaped light sensitive film. A transmitted-light strength in a point where the axis of ordinates and the transmitted-light strength cross each other corresponds to I


CENTER


, and a transmitted-light strength in a point where the chain line in parallel with the axis of ordinates and the transmitted-light strength cross each other corresponds to I


EDGE


.




As shown in

FIGS. 11

to


16


, in an area of the transmitted-light strength in which area the transmitted-light strength on the light sensitive film


20


decreases (first) along the horizontal direction (x-direction), the electron beam sweep direction, from the central portion of the stripe-shaped exposed region corresponding the opening portion, the derivative of the first order (∂I/∂x) of the superposed transmitted-light strength has at least one upward-convex area. And, the edge portion (see chain lines a, b, c, d, e and f in parallel with the axis of ordinates) of the exposed stripe-shaped light sensitive film corresponding to the opening portion is included in an area of the superposed transmitted-light strength corresponding to the upward-convex area (first wave) appearing first along the horizontal direction of the face plate, the electron beam sweep direction, from the central portion of the stripe-shaped exposed region, out of the upward-convex areas of the derivative of the first order (∂I/∂x) of the superposed transmitted-light strength.




In

FIGS. 11

,


12


,


13


and


14


, due to the superposing of the two exposure lights, the transmitted-light strength on the light sensitive film


20


increases first and then decreases along the horizontal direction (x-direction) of the face plate from the central portion of the stripe-shaped exposed region. In this increasing area, the derivative of the first order (∂I/∂x) of the transmitted-light strength also has an upward-convex area. However, this upward-convex area is not the “upward-convex area which appears first (first wave)”.




For forming fluorescent material layers for red, green and blue, the above exposure procedures were carried out three times (total six times) with regard to each color by changing the exposure light sources. In this manner, stripe-shaped exposed regions were formed in the light sensitive film formed on the entire of inner surface of the face plate. In this case, no convexo-concave shapes were observed in edge portions of the obtained exposed regions, and each of the edge portions was in the form of a straight line.




Then, the light sensitive film


20


is selectively removed by development, and a remaining portion


22


of the light sensitive film (light sensitive film after the exposure and development) is retained on the inner surface


11


A of the face plate


11


(see FIG.


47


C). Then, a carbon agent (carbon slurry) is applied to the entire surface, dried and calcined or sintered, and then, the remaining portion


22


of the light sensitive film and the carbon agent thereon are removed by a lift-off method, to form a stripe-shaped black-matrix


23


composed of the carbon agent on the exposed inner surface


11


A of the face plate


11


in the form of a stripe and also to remove the remaining portion


22


of the light sensitive film (see FIG.


48


A). Then, stripe-shaped fluorescent material layers


24


for red, green and blue are formed on the exposed inner surface


11


A (portion


11


B of the inner surface


11


A exposed between black-matrixes (light absorption layers)


23


) of the face plate


11


(see FIG.


48


B). Specifically, for example, a photosensitive fluorescent material slurry for red is applied to the entire surface, followed by exposure and development, then, a photosensitive fluorescent material slurry for green is applied to the entire surface, followed by exposure and development, and a photosensitive fluorescent material slurry for blue is applied to the entire surface, followed by exposure and development. Then, the face plate and a funnel, etc., are assembled, to complete a bulb for a color cathode ray tube. Further, an electron gun is incorporated into the obtained bulb, and the inside of the bulb is vacuumed, to complete a color cathode ray tube.




The thus-obtained color cathode ray tube was used to display images, to show no non-uniformity in displayed images, so that the obtained color cathode ray tube had excellent qualities.




EXAMPLE 2




Example 1 used two exposure light sources. However, on exposure of the light sensitive film, the central portion thereof in particular, is insufficiently exposed with some exposure apparatus or under some exposure conditions. In such a case, when the light sensitive film


20


is developed and selectively removed to retain a remaining portion


22


of the light sensitive film (light sensitive film after exposure and development) on the inner surface


11


A of the face plate


11


, those portions of the light sensitive film which portions correspond to the central portions of the opening portions are not retained as shown in a schematic partial cross-sectional view of the light sensitive film retained on the face plate, as shown in

FIGS. 53A and 53B

. For reliably preventing the above phenomenon, it is required to use three or more exposure light sources.




Example 2 is a variant of Example 1. Differing from Example 1, Example 2 used three exposure light sources. Of three exposure light sources


31


A,


31


B and


31


C, two exposure light sources


31


A and


31


C positioned outside correspond to exposure light sources for exposing an edge portion, and the exposure light source


31


B positioned between the exposure light sources


31


A and


31


C for exposing an edge portion corresponds to an exposure light source for exposing a central portion. The bulb for a color cathode ray tube in Example 2 is structurally the same as the bulb for a color cathode ray tube explained in Example 1, so that a detailed explanation thereof is omitted. In Example 2, the above expressions (1) and (2) are also satisfied. Further, in Example 2, the value of P×LT×GH


−1/2


was also set at 3.4×10


−2


. In the transmitted-light strength of superposed Fresnel diffraction waves of the exposure lights from the three exposure light sources


31


A,


31


B and


31


C, further, I


CENTER


/I


EDGE


≧1.2 is satisfied, wherein I


CENTER


is a transmitted-light strength in the central portion of an exposed region corresponding to each opening portion and I


EDGE


is a transmitted-light strength in an edge portion of the light sensitive film corresponding to each opening portion. Further, when the exposure light sources


31


A and


31


C for exposing an edge portion were individually operated to expose the light sensitive film formed on the inner surface of the face plate, each of the exposure light sources for exposing an edge portion was adjusted to satisfy I


MIN


≦I


1


, wherein I


1


is a transmitted-light strength in an edge portion of the light sensitive film corresponding to each opening portion and IMIN is the lowest transmitted-light strength required for exposing the light sensitive film.




The bulb or the color cathode ray tube in Example 2 can be produced by the step of exposing the light sensitive film


20


formed on the inner surface


11


A of the face plate


11


on the basis of a transmitted-light strength distribution of superposed Fresnel diffraction waves of the exposure lights which are emitted from a plurality of exposure light sources (the three exposure light sources


31


A,


31


B and


31


C in Example 2) arranged in different positions along the electron beam sweep direction (specifically, the horizontal direction of the face pate


11


) and pass through the opening portions (slits


14


) formed in the color selection member


13


, to form exposed regions (more specifically, stripe-shaped exposed regions) in the light sensitive film


20


corresponding to the opening portions (the slits


14


), so long as the expressions (1) and (2) are satisfied.




The method for producing a bulb for a color cathode ray tube in Example 2 is a method for a bulb for a color cathode ray tube which bulb comprises a face plate


11


and a color selection member


13


of aperture grille type having stripe-shaped slits


14


(corresponding to a plurality of the opening portions) extending in parallel with the vertical direction (y-direction) of the face plate


11


and satisfies the above expression (1), wherein X is a nominal diagonal inchage of the bulb and P (unit: mm) is a pitch of the opening portions along the electron beam sweep direction (x-direction) in the central portion of the bulb (more specifically, a pitch of the slits


14


). Further, the method for producing a color cathode ray tube in Example 2 is a method for producing a color cathode ray tube comprising the above bulb.




In practicing the method for producing a bulb for a color cathode ray tube or the method for producing a color cathode ray tube in Example 2 (to be generally referred to as “production method of Example 2” hereinafter), three exposure light sources (ultraviolet light sources


31


A,


31


B and


31


C in an example shown in

FIG. 4

) are used, and as shown in

FIG. 4

, are arranged in different positions along the horizontal direction (x-direction) of the face plate, the electron beam sweep direction. Of the three exposure light sources


31


A,


31


B and


31


C, the two exposure light sources


31


A and


31


C positioned outside correspond to exposure light sources for exposing an edge portion, and the exposure light source


31


B positioned between the two exposure light sources


31


A and


31


C for exposing an edge portion corresponds to an exposure light source for exposing a central portion. Further, a correction lens system is disposed between the exposure light sources


31


A,


31


B and


31


C and the color selection member


13


. The correction lens system comprises an illumination correction filter


32


, first correction lenses


33


A,


33


B and


33


C and a second correction lens group


34


, which are positioned in this order from the exposure light source side. The illumination correction filter


32


serves to optimize the size (width) of the fluorescent material layers to be obtained on the entire surface of the face plate


11


. The second correction lenses group


34


made of glass serves to approximate the paths of the exposure lights during the exposure to the paths of actual electron beams.




Further, when the first correction lenses


33


A,


33


B and


33


C made of glass are provided, there can be attained a large value of the derivative of the first order (∂I/∂x) of the transmitted-light strength in the edge portion of the exposed stripe-shaped light sensitive film all over the inner surface of the face plate, and the edge portions of the exposed stripe-shaped light sensitive film can be included in an area of the transmitted-light strength which area corresponds to the first wave of the derivative of the first order (∂I/∂x). When the light sensitive film is exposed to the light from one exposure light source


31


A, the first correction lens


33


A is used, when the light sensitive film is exposed to the light from the exposure light source


31


B for exposing an central portion, the first correction lens


33


B is used, and when the light sensitive film is exposed to the light from the other exposure light source


31


C, the first correction lens


33


C is used. The first correction lens


33


A and the first correction lens


33


C have identical characteristics (but symmetrical characteristic with regard to a z-axis shown in FIG.


4


). Each of the first correction lenses


33


A,


33


B and


33


C has a smooth convexo-concave shape formed on one surface.




Specifically, the first correction lenses


33


A,


33


B and


33


C for correcting Fresnel diffraction conditions are selected depending upon the exposure light sources used. In the exposure apparatus, the three exposure lights emitted from the three exposure light sources


31


A,


31


B and


31


C are adjusted such that their Fresnel diffraction waves are superposed on the light sensitive film


20


through the correction lens system


32


,


33


A,


33


B,


33


C,


34


and the color selection member


13


so that the light sensitive film


20


is exposed in the form of a stripe having a predetermined width depending upon the slit corresponding to the opening portion. Further, the exposure lights are adjusted such that the value of the derivative of the first order (∂I/∂x) of the transmitted-light strength corresponding to the edge portions of the exposed stripe-shaped light sensitive film comes to be a value of a certain level or higher.




In the production method of Example 2, the face plate


11


having the inner surface


11


A on which the light sensitive film


20


is formed (applied) is also prepared (see FIG.


47


A). The light sensitive film


20


formed (applied) on the inner surface


11


A of the face plate


11


is exposed (see

FIGS. 4 and 5

) to form stripe-shaped exposed regions


21


in the light sensitive film


20


corresponding to the slits (see

FIG. 47B

) on the basis of the transmitted-light strength distribution of superposed Fresnel diffraction waves of the exposure lights which are emitted from a plurality of the exposure light sources


31


A,


31


B and


31


C (three exposure light sources in Example 2) arranged in different positions along the horizontal direction of the face plate (x-direction), the electron beam sweep direction, and which pass through the slits


14


corresponding to the opening portions formed in the color selection member


13


.

FIG. 6

schematically shows, by a solid line, one example of each transmitted-light strength distribution of a Fresnel diffraction wave of each of the three exposure lights which pass through one slit


14


. A convexo-convex curved portion shown by a dotted line indicates a portion of a transmitted-light strength distribution in which portion the three exposure lights are superposed, that is, part of transmitted-light strength distribution of superposed Fresnel diffraction waves of the three exposure lights.





FIGS. 17

,


18


,


19


,


20


,


21


and


22


show results of measurement of transmitted-light strength distributions of superposed Fresnel diffraction waves of the three exposure lights which pass through the slits


14


in coordinates (0,211), (0,0), (128,211), (128,0), (375,211) and (375,0) where the nominal diagonal inchage X of the bulb


10


is 36 (X=36), the center of the face plate


11


is an origin, a straight line extending in the horizontal direction (x-direction) of the face plate and passing through the origin is an x-axis and a straight line extending in the vertical direction (y-direction) of the face plate and passing through the origin is a y-axis. The unit of values in the coordinates is “mm”. In each drawing, the derivative of the first order (∂I/∂x) of the transmitted-light strength is shown by a dotted line.




The transmitted-light strength distributions of superposed Fresnel diffraction waves of the exposure lights from the two exposure light sources contributing to the exposure of the edge portions of the light sensitive film (exposure light sources


31


A and


31


C for exposing an edge portion) corresponding to the opening portion, out of the three exposure light sources


31


A,


31


B and


31


C, are the same as the transmitted-light strength distributions shown in

FIGS. 11

to


16


. That is, in an area of the transmitted-light strength in which area the transmitted-light strength on the light sensitive film


20


decreases (first) along the horizontal direction of the face plate (x-direction), the electron beam sweep direction, from the central portion of the stripe-shaped exposed region corresponding the opening portion, the derivative of the first order (∂I/∂x) of the superposed transmitted-light strength has at least one upward-convex area. And, the edge portion (see chain lines a, b, c, d, e and f in parallel with the axis of ordinates) of the exposed stripe-shaped light sensitive film corresponding to the opening portion is included in an area of the superposed transmitted-light strength which area corresponds to the upward-convex area (first wave) appearing first along the horizontal direction of the face plate, the electron beam sweep direction, from the stripe-shaped exposed region, out of the upward-convex areas of the derivative of the first order (∂I/∂x) of the superposed transmitted-light strength.




In

FIG. 18

, due to the superposing of-the three exposure lights, the derivative of the first order (∂I/∂x) of the transmitted-light strength on the light sensitive film


20


has an upward-convex area in the vicinity of the central portion of the exposed region. This upward-convex area (indicated by a symbol “A” in

FIG. 18

) is caused by the exposure light from the exposure light source


31


B for exposing a central portion.




For forming fluorescent material layers for red, green and blue, the above exposure procedures were carried out three times (total nine times) with regard to each color by changing the exposure light sources. In this manner, stripe-shaped exposed regions were formed in the light sensitive film formed on the entire of inner surface of the face plate. In this case, no convexo-concave shapes were observed in edge portions of the obtained exposed regions, and each of the edge portions was in the form of a straight line.




Then, finally, stripe-shaped fluorescent material layers


24


for red, green and blue are formed, and the face plate, a funnel, etc., are assembled, in the same manner as in Example 1, to complete a bulb for a color cathode ray tube. Further, an electron gun is incorporated into the obtained bulb, and the inside of the bulb is vacuumed to complete a color cathode ray tube.




The color cathode ray tube as an end product was used to display images, to show no non-uniformity in displayed images, so that the obtained color cathode ray tube had excellent qualities.




COMPARATIVE EXAMPLE 1




There was produced a bulb for a color cathode ray tube which satisfied the above expression (1) but did not satisfy the expression (2). This Example employed P×LT×GH


−1/2


=4.2×10


−2


. Further, one exposure light source was used. The nominal diagonal inchage X of the bulb


10


was 36 (X=36). Transmitted-light strength distributions of a Fresnel diffraction wave of the exposure light which passed through slits in coordinates (0,198), (0,0), (192,198), (192,0), (375,198) and (375,0) were measured, and

FIGS. 23

,


24


,


25


,


26


,


27


and


28


show the results by a solid line each. In each drawing, the derivative of the first order (∂I/∂x) of the transmitted-light strength is shown by a dotted line.




The produced color cathode ray tube was used to display images, to show non-uniformity in displayed images, and the quality of the color cathode ray tube was partly degraded to a great extent. The image display non-uniformity was distinctively observed around the coordinates of (192,198) and (192,0). When the above phenomenon and the measurement results in

FIGS. 23

to


28


were compared, edge portions of the exposed stripe-shaped light sensitive film (see chain lines c and d in parallel with the axis of ordinates) were included in a transition area from the first wave to the second wave as is clearly shown in

FIGS. 25 and 26

in particular. Further, when the light sensitive film was selectively removed by exposure and development, edge portions of remaining portion of the light sensitive film were caused to have heavy convexo-concave shapes.




COMPARATIVE EXAMPLE 2




There was produced a bulb for a color cathode ray tube which satisfied the above expression (1) but did not satisfy the expression (2). This Example employed P×LT×GH


−1/2


=4.2×10


−2


. Further, two exposure light sources were used. The nominal diagonal inchage X of the bulb


10


was 36 (X=36). Transmitted-light strength distributions of superposed Fresnel diffraction waves of the two exposure lights which passed through slits in coordinates (0,198), (0,0), (128,198), (128,0), (375,198) and (375,0) were measured, and

FIGS. 29

,


30


,


31


,


32


,


33


and


34


show the results by a solid line each. In each drawing, the derivative of the first order (∂I/∂x) of the transmitted-light strength is shown by a dotted line.




The produced color cathode ray tube was used to display images, to show non-uniformity in displayed images, and the quality of the color cathode ray tube was partly degraded to a great extent. The image display non-uniformity was distinctively observed around the coordinates of (0,198) and (128,0). When the above phenomenon and the measurement results in

FIGS. 29

to


34


were compared, edge portions of the exposed stripe-shaped light sensitive film (see chain lines a and d in parallel with the axis of ordinates) were included in a transition area from the first wave to the second wave as is clearly shown in

FIGS. 29 and 32

in particular. Further, when the light sensitive film was selectively removed by exposure and development, edge portions of remaining portion of the light sensitive film were caused to have heavy convexo-concave shapes.




COMPARATIVE EXAMPLE 3




There was produced a bulb for a color cathode ray tube which satisfied the above expression (1) but did not, satisfy the expression (2). This Example employed P×LT×GH


−1/2


=4.2×10


−2


. Further, three exposure light sources were used. The nominal diagonal inchage X of the bulb


10


was 36 (X=36). Transmitted-light strength distributions of superposed Fresnel diffraction waves of the three exposure lights which passed through slits in coordinates (0,198), (0,0), (128,198), (128,0), (375,198) and (375,0) were measured, and

FIGS. 35

,


36


,


37


,


38


,


39


and


40


show the results by a solid line each. In each drawing, the derivative of the first order (∂I/∂x) of the transmitted-light strength is shown by a dotted line.




The produced color cathode ray tube was used to display images, to show non-uniformity in displayed images, and the quality of the color cathode ray tube was partly degraded to a great extent. The image display non-uniformity was distinctively observed around the coordinate of (128,198). When the above phenomenon and the measurement results in

FIGS. 35

to


40


were compared, edge portions of the exposed stripe-shaped light sensitive film (see a chain line c in parallel with the axis of ordinates) were included in a transition area from the first wave to the second wave as is clearly shown in

FIG. 37

in particular. Further, when the light sensitive film was selectively removed by exposure and development, edge portions of remaining portion of the light sensitive film were caused to have heavy convexo-concave shapes.




COMPARATIVE EXAMPLE 4




There was produced a bulb for a color cathode ray tube which satisfied the above expressions (1) and (2). This Example employed P×LT×GH


−1/2


=3.4×10


−2


. However, differing from Example 1, Comparative Example 4 used one exposure light source. The nominal diagonal inchage X of the bulb


10


was 36 (X=36). Transmitted-light strength distributions of a Fresnel diffraction wave of the exposure light which passed through slits in coordinates (0,211), (0,0), (128,211), (128,0), (375,211) and (375,0) were measured, and

FIGS. 41

,


42


,


43


,


44


,


45


and


46


show the results by a solid line each. In each drawing, the derivative of the first order (∂I/∂x) of the transmitted-light strength is shown by a dotted line.




The produced color cathode ray tube was used to display images, to show non-uniformity in displayed images, and the quality of the color cathode ray tube was partly degraded to a great extent. The image display non-uniformity was distinctively observed around the coordinate of (128,211). When the above phenomenon and the measurement results in

FIGS. 41

to


46


were compared, edge portions of the exposed stripe-shaped light sensitive film (see a chain line c in parallel with the axis of ordinates) were included in a transition area from the first wave to the second wave as is clearly shown in

FIG. 43

in particular. Further, when the light sensitive film was selectively removed by exposure and development, edge portions of remaining portion of the light sensitive film were caused to have heavy convexo-concave shapes.




The following Table 1 summarizes the numbers of the exposure light sources and the values of P×LT×GH


−1/2


in Examples 1 and 2 and Comparative Examples 1 to 4.















TABLE 1











Number of exposure








light sources




P × LT × GH


−1/2






























Ex. 1




2




3.4 × 10


−2









Ex. 2




3




3.4 × 10


−2









CEx. 1




1




4.2 × 10


−2









CEx. 2




2




4.2 × 10


−2









CEx. 3




3




4.2 × 10


−2









CEx. 4




1




3.4 × 10


−2















Ex. = Example, CEx. = Comparative Example













While the present invention has been explained with reference to Examples hereinabove, the present invention shall not be limited thereto. The structures of the bulb for a color cathode ray tube and the color cathode ray tube and the constitution of the exposure apparatus are shown as examples, and the methods for producing these are also shown as examples, so that they can be modified or altered as required. In Examples, the color selection members of aperture grille type have been explained. However, other dot-type or slot-type shadow mask type color selection members may be used. Further, the electron beam sweep direction shall not be limited to the horizontal direction (x-direction) of the face plate, and in some structures of the bulb for a color cathode ray tube and the color cathode ray tube, the electron beam sweep direction can be the vertical direction (y-direction) of the face plate.




In the present invention, the edge portions of the light sensitive film remaining after exposure and development are not caused to have convexo-concave shapes. Further, in the bulb for a color cathode ray tube or the color cathode ray tube of the present invention, no convexo-concave shapes are formed in the edge portions of the fluorescent material layer. Therefore, even if the bulb for a color cathode ray tube or the color cathode ray tube for digital broadcasting for which the pitch of the opening portions of the color selection member in the central portion of the bulb is an intermediate range between the pitch of the opening portions of the color selection member in a commercial color cathode ray tube and the pitch of the opening portions of the color selection member in a high-resolution color cathode ray tube for a computer display, no non-uniformity in displayed images is observed, and there can be provided color cathode ray tubes having stable high qualities.



Claims
  • 1. A method for producing a bulb for a color cathode ray tube, the bulb having a face plate and a color selection member having a plurality of opening portions,the method comprising the step of exposing a light-sensitive film formed on an inner surface of the face plate based upon a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure light that are emitted from a plurality of exposure light sources arranged along an electron beam sweep direction and that pass through the opening portions formed in the color selection member to form exposed regions in the light sensitive film corresponding to the opening portions, wherein X is a nominal diagonal dimension of the bulb, P is a pitch of The opening portions along the electron beam sweep direction in a central portion of the bulb, and a transmitted-light strength of the superposed Presnel diffraction waves of two exposure lights of the plurality of exposure lights contributing to an exposure of edge portions of the light sensitive film corresponding to each opening portion satisfies: a first-order derivative of the transmitted-light strength has an upward-convex area in an area of the transmitted-light strength in which the transmitted-light strength on the light sensitive film decreases along the electron beam sweep direction from a central portion of the exposed region of the light sensitive film corresponding to each opening portion; the edge portions of the exposed light sensitive film corresponding to each opening portion are included in an area of the transmitted-light strength corresponding to the upward-convex area which appears first along the electron beam sweep direction from the central portion of the exposed region corresponding to each opening portion, out of the upward-convex areas of the first-order derivative of the transmitted-light strength; and 0.0117X−0.0457<P<0.018X−0.0771.
  • 2. The method for producing a bulb for a color cathode ray cube according to claim 1, wherein OH is a distance between the inner surface of the face plate and the color selection member in the central portion of the bulb; LI is a value obtained by dividing a size of the opening portion along the electron beam sweep direction in the central portion of the bulb by the pitch P; and2.8×10−2<P×LT×GH−1/2<4.1×10−2.
  • 3. The method for producing a bulb for a color cathode ray tube according to claim 1, wherein after formation of the exposed regions in the light sensitive film formed on the inner surface of the face plate corresponding to the openings, the method further comprises the steps of: selectively removing the light sensitive film by development; forming a light-absorption layer on the exposed inner surface of the face plate and removing a remaining portion of the light sensitive film; and forming a fluorescent material layer on the exposed inner surface of the face plate.
  • 4. The method for producing a bulb for a color cathode ray tube according to claim 1, wherein a correction lens system is disposed between the exposure light sources and the color selection member.
  • 5. The method for producing a bulb for a color cathode ray tube according to claim 1, claim 2, claim 3, or claim 4, wherein the number of the exposure light sources is two.
  • 6. The method for producing a bulb for a color cathode ray tube according to claim 1, claim 2, claim 3, or claim 4, wherein the number of the exposure light sources is at least three ICENTER is the transmitted-light strength in the central portion of the exposed region corresponding to each opening portion; IEDGE is a transmitted-light strength in the edge portion of the light sensitive film corresponding to each opening portion; and the transmitted-light strength of superposed Fresnel diffraction waves of the exposure lights from all of the exposure light sources satisfies an expression ICENTER/IEDGE1.2.
  • 7. A method for producing a color cathode ray tube having a bulb, the bulb having a face plate and a color selection member having a plurality of opening portions,the method comprising the step of exposing a light-sensitive film formed on an inner surface of the face plate based upon a transmitted-light strength distribution of superposed Fresnel diffraction waves of exposure light emitted from a plurality of exposure light sources arranged along the electron beam sweep direction and pass through the opening portions formed in the color selection member to form exposed regions in the light sensitive film which regions correspond to the opening portions, wherein X is a nominal diagonal dimension of the bulb, P is a pitch of the opening portions along an electron beam sweep direction in the central portion of the bulb, and a transmitted-light strength of superposed Presnel diffraction waves of two exposure lights out of the plurality of exposure lights emitted from two exposure light sources contributing to an exposure of edge portions of the light sensitive film corresponding to each opening portion satisfies: a first-order derivative of the transmitted-light strength has at least one upward-convex area in an area of the transmitted-light strength where the transmitted-light strength on the light sensitive film decreases along the electron beam sweep direction from a central portion of the exposed region of the light sensitive film corresponding to each opening portion; the edge portions of the exposed light sensitive film corresponding to each opening portion are included in an area of the transmitted-light strengch corresponding to the upward-convex area which appears first along the electron beam sweep direction from the central portion of the exposed region corresponding to each opening portion, out of the upward-convex areas of the derivative of the first order of the transmitted-light strength; and 0.0117X−0.0457<P<0.018X−0.0771.
  • 8. The method for producing a color cathode ray tube according to claim 7, wherein GH is a distance between the inner surface of the face plate and the color selection member in the central portion of the bulb; LT is a value obtained by dividing a size of the opening portion along the electron beam sweep direction in the central portion of the bulb by the pitch P; and2.8×10−2<P×LT×GH−1/2<4.1×10−2.
  • 9. The method for producing a color cathode ray tube according to claim 7 or claim 8, wherein the number of exposure light sources is two.
  • 10. The method for producing a color cathode ray tube according to claim 7 or claim 8, wherein the number of exposure light sources is at least 3; ICENTER is the transmitted-light strength in the central portion of the exposed region corresponding to each opening portion; IEDGE is the transmitted-light strength in the edge portion of the light sensitive film corresponding to each opening portion; and the transmitted-light strength of the superposed Fresnel diffraction waves of the exposure light satisfies the expression: ICENTER/IEDGE21/2.
Priority Claims (2)
Number Date Country Kind
P2000-000495 Jan 2000 JP
P2000-201501 Jul 2000 JP
US Referenced Citations (2)
Number Name Date Kind
4070498 Nishizawa et al. Jan 1978 A
4696879 Yamazaki et al. Sep 1987 A
Foreign Referenced Citations (4)
Number Date Country
0146226 Jun 1985 EP
60109133 Jun 1985 JP
61234028 Dec 1986 JP
10162731 Jun 1998 JP