

CRT TUBE TOSHIBA UNITIZED Electron gun
An
electron gun comprising a plurality of focusing grids spatially
arranged along the path of an electron beam generated from a cathode and
each bored with at least one opening for allowing the passage of the
electron beam, wherein at least one of said plural focusing grids is
formed of at least one electrode set at a grounding potential or a
lower potential than a focusing voltage and at least one more
electrode whose potential is defined by an electrostatic capacity; and
a high voltage is produced to provide an electron lens, though
enabling the electron lens to improve its performance without being
obstructed by requirements associated with the construction of a
picture tube.
1. An electron gun comprising a plurality of focusing grids spatially
arranged along the path of an electron beam generated from a cathode
and each bored with at least one opening for allowing passage of the
electron beam, wherein at least one of said plural focusing grids is
formed between two other grids and includes a second electrode set at a
grounding potential or a lower potential than a focusing voltage, and
first and third electrodes arranged on opposite sides of said second
electrode along the electron beam path and electrically connected with
each other, the potentials of said first and third electrodes being
defined by the potentials of said two other grids and the potential of
said second electrode and by the capacitance between said first
electrode and the adjacent other grid, the capacitance between said
first electrode and said second electrode, the capacitance between said
third electrode and the adjacent other grid and the capacitance
between said third electrode and said second electrode.
2. The electron gun according to claim 1,
wherein the second electrode is grounded through a variable capacitor.
This invention relates to an electron gun for generating one or more electron beams and more particularly to an electron gun provided with means for effectively focusing the electron beams on a target.
With the ordinary color picture tube provided with a multi-beam electron gun designed to generate a plurality of electron beams, the respective electron beams pass through separate electron lenses to be focussed at a point on a target. The electron lens is generally formed of a static electric field to focus the electron beams at a single point. The static electric field is formed at right angles to an electron beam path, and is disposed between at least two electrodes each bored with an opening allowing the passage of an electron beam. The properties of the electron lens can generally be varied according to interelectrode voltage, the size of an opening bored in the electrodes and a distance therebetween.
The electron gun is generally regarded to have a more improved performance, according as the electron lens is more reduced in the degree of magnification and spherical aberration. To provide an electron gun of high quality, therefore, it is necessary to extend the focal length of the electron lens. The most effective process to attain this object is to vary interelectrode voltage. However, the level of the interelectrode voltage should generally be restricted to fall within such a range as prevents arcing from taking place at the base portion of a picture tube. Further, enlargement of an electrode opening to extend the focal length of the electron lens is subject to certain limitations, because the neck diameter of the picture tube is restricted by other electrical requirements. Moreover, extension of the interelectrode distance is not advisable since the properties of the electron lens are harmfully affected by a electric charge occurring in the neck portion of the picture tube and the generation of an unnecessary electric field in the electron gun. As mentioned above, the design of the electron lens is subject to limitations due to various physical requirements associated with the construction of a picture tube. These limitation are particularly rigid in the case of a color picture tube using a multi-beam electron gun.
The customary process of manufacturing an electron lens having a long focal length without being obstructed by the above-mentioned limitations is to combine properly interelectrode voltage and the kind of electrode. An electron gun constructed by the above-mentioned process has already beam set forth in the Japanese patent disclosures Nos. 76072/1976 and 77061/1976.
However, the disclosed processes have the drawbacks that the electron gun unavoidably has a complicated construction and extra voltage has to be applied to improve the formation of an electron lens, thus leading to economic disadvantage. For elevation of the performance of an electron lens, it is necessary to apply high voltage with respect to not only the electron guns used in the above-mentioned disclosed processes but also electron guns in general use. In such a case, a special device has to be provided to suppress arcing which might otherwise occur in the base portion of a picture tube in order to ensure its reliable operation, thus rendering the picture tube more expensive.
SUMMARY OF THE INVENTION
It is accordingly the object of this invention to provide an electron gun admitting of the elevation of the performance of an electron lens without being obstructed by requirements associated with the construction of a picture tube.
According to this invention, there is provided an electron gun comprising a plurality of focusing grids spatially arranged along the path of an electron beam generated from a cathode and each bored with at least one opening for allowing the passage of the electron beam, wherein at least one of said plural focusing grids is formed of at least one electrode set at a grounding potential or a lower potential than the focusing voltage and at least one more electrode whose potential is defined by an electrostatic capacity.
BRIEF DESCRIPTION OF THE DRAWING
FIG. 1A is a front view of an electron gun according to one embodiment of this invention;
FIG. 1B is a plan view of the electron gun of FIG. 1A;
FIG. 2 is a sectional view of the electron gun of FIG. 1A;
FIG. 3 shows an equivalent circuit of the electron gun of FIG. 2;
FIG. 4 is a sectional view of a modification of a fourth focusing grid used with the electron gun of FIG. 2;
FIG. 5 schematically illustrates a modification of the electron gun of FIG. 1; and
FIG. 6 is a sectional view of an electron gun according to another embodiment of this invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
For an electron gun embodying this in

There will now be described by reference to the accompanying drawing the cases where this invention is applied to a uni-potential type electron gun and a bi-potential type electron gun. Description is first given of the case where this invention is applied to the uni-potential type electron gun. FIGS. 1A, 1B and 2 are respectively a front view, plan view and sectional view of an in-line type electron gun used with a color picture tube. An electron gun 1 comprises a plurality of electrodes and glass supports thereof. The plural electrodes constitute these cathodes 2, 3, 4, first grid 5, second grid 6, third grid or first focusing grid 7, fourth grid or third focusing grid 8 and fifth grid or second focusing grid 9. These grids are fitted to the glass supports 10 in the order mentioned as counted from the cathode side. The cathodes 2, 3, 4, send forth electron beams along three paths lying on the same plane. The first grid 5 and second grid 6 are flat electrodes closely facing each other and are respectively bored with a group of three openings 11-12-13 and another group of three openings 14-15-16 which are aligned with the three electron beam paths. The third grid or first focusing grid 7 is positioned adjacent to the second grid 6. The grid 7 is formed of a pair of cups 20, 21 joined with each other on the peripheral edges of the openings thereof. The bottoms of said cups 20, 21 are respectively bored with a group of three openings 17-18-19 and another group of three openings 22, 23, 24 which are aligned with the three electron beam paths. The openings 17, 18, 19 of the first cup 20 have a larger diameter than the openings 14, 15, 16 of the second grid 6. The openings 22, 23, 24 of the second cup 21 have a larger diameter than the openings 17, 18, 19 of the first cup 20. The fourth grid or third focusing grid 8 is formed of at least three auxiliary electrodes 25, 26, 27. The first electrode 25 and third electrode 27 are respectively formed of a pair of cups joined with each other. Both electrodes 25, 27 are respectively bored with a group of three openings 28-29-30 and another group of three openings 33-34-35 which are aligned with the three electron beam paths. Said electrodes 25, 27 are electrically connected together to have the same potential, and spatially arranged along the electron beam paths. Provided between the electrodes 25, 27 is a plate-shaped second electrode 26, which is also bored with three openings aligned with the three electron beam paths. The fifth grid or second focusing grid 9 is cup-shaped, spaced from the fourth grid 8 substantially as much as a distance between the third grid 7 and fourth grid 8, and also bored with three openings 36, 37, 38. The central opening 37 is aligned with the axis 43 of the central opening of the first grid 5 to that of the fourth grid 8. But the other openings 36, 38 are respectively slightly displaced outward from the axes 44 of the side openings of the first grid 5 to that of the fourth grid 8. The displacement is intended to caus

The grids of the electron gun are spaced from each other as follows.
______________________________________ |
A distance between the third grid or first focusing grid 7 and the first electrode 25 of the fourth grid or about 1 mm third focusing grid 8 A distance between the third electrode 27 of the fourth grid or third focusing about 1 mm grid 8 and the fifth grid or second focusing grid 9 A distance between the second electrode 26 and the first electrode 25 of the about 0.6 mm fourth grid or third focusing grid 8 A distance between the second electrode 26 and the third electrode 27 of the about 0.6 mm fourth grid or third focusing grid 8 |
______________________________________ |
When an electron gun is built in a picture tube, the bulb spacers 45 are pressed against the inner wall of the picture tube, thereby electrically connecting the fifth grid 9 to the inner wall of the picture tube. During the operation of the electron gun, the third grid 7 and fifth grid 9 are applied with voltage of about 25 to 30 kv through the inner wall of the picture tube. The second electrode 26 of the fourth grid 8 is grounded through the base portion of the picture tube. At the time, the first electrode 25 and third electrode 27 of the fourth grid 8 are naturally applied with voltage of about 10 kv. The reason why this voltage is naturally generated in the first and third electrodes 25, 27 of the fourth grid 8 may be explained as follows by reference to the equivalent circuit of FIG. 3.
Two capacitors

Referring to the equivalent circuit of FIG. 3, the two capacitors C 1 and the two other capacitors C 2 are respectively connected in series. The character M 1 denotes the third grid 7; the character M 2 the fifth grid 9; the charactor L 1 the first electrode 25; the character L 2 the third electrode 27; and the character N the second electrode 26. Where voltage of, for example, 25 kv is applied on the third grid 7 or M 1 and the fifth grid 9 or M 2 , and the second electrode 26 or N is set at a grounding potential, then voltage corresponding to the capacities of two capacitors C 1 , C 2 constituting one set is generated in the first electrode 25 or L 1 , and voltage corresponding to the capacities of two capacitors C 1 , C 2 constituting another set is generated in the third electrode 27 or L 2 . The capacities of the capacitors C 1 , C 2 are defined only by a distance between the respective electrodes constituting said capacitors, if the electrodes have substantially the same shape. Where, therefore, levels of voltage being applied on the first and third electrodes 25, 27 of the fourth grid 8 are selected in designing an electron gun, then a ratio which a distance between the electrodes constituting the capacitor C 1 bears to a distance between the electrodes constituting the capacitor C 2 is defined. Conversely speaking, where the ratio between said distances is chosen, then values of voltage applied on the first and third electrodes 25, 27 of the fourth grid 8 are determined. Values of the above-mentioned voltage and distance are practically decided as follows. An electron gun in which all the electrodes constituting the fourth grid 8 have the same potential represents the ordinary uni-potential type. Where this type of electron gun is designed by setting the focusing voltage (voltage impressed on the fourth grid 8) at 10 kv when voltage of 25 kv is applied on the third and fifth grids 7, 9, then it is advised to set a distance between the first and second electrodes 25, 26 of the fourth grid 8 and that between the second and third electrodes 26, 27 thereof and ground the second electrode 26. Assuming that a distance between the third grid 7 and first electrode 25, and a distance between the fifth grid 9 and third electrode 27, that is, distances between the electrodes respectively constituting the two capacitors C 1 are chosen to be 1 mm, then a distance between the first and second electrodes 25, 26 of the fourth grid 8 and a distance between the second and third electrodes 26, 27 thereof, that is, distances between the electrodes respectively constituting the two other capacitors C 2 are calculated to be 0.67 mm, as measured from the following equation: ##EQU1##
What should be taken into consideration in adopting the above-mentioned method of designing an electron gun, is to prevent the potential of the second electrode 26 of the fourth grid 8 from exerting a harmful effect on an electron lens. Namely, it is necessary, for example, to bore the second electrode 26 of the fourth grid 8 with three openings larger than those of the first and third electrode 25, 27 thereof and, where required, construct the fourth grid 8 as illustrated in FIG. 4, thereby preventing an electrostatic field created by the second electrode 26 from substantially exerting a harmful effect on the function of an electron gun particularly, an electron lens. The fourth grid of FIG. 4 is formed of a first electrode 47, second electrode 48 and third electrode 49. The peripheral edges of the three openings bored in the first electrode 47 and those of the third electrode 49 projects towrard the second electrode 48. If however, an electrostatic field generated in the neighborhood of the second electrode does not substantially exert any harmful effect on the function of an electron lens, then it is unnecessary to construct the fourth grid 8 as shown in FIG. 4. It is obviously possible positively to utilize an electrostatic field produced in the proximity of the second electrode 48. In such case, the interelectrode distance can not be determined by the previously described method.

Rigidly speaking, an electrostatic capacity is not defined solely by a distance between two mutually facing electrodes or other factors thereof, but is actually affected by the properties of other electrodes and earth capacity. Practically, therefore, a proper interelectrode distance has to be experimentally determined.
FIG. 5 schematically shows the arrangement of a modification of focusing means used with an electron gun embodying this invention. This focusing means is formed of a first focusing grid 52, second focusing grid 53 and third focusing grid 54. The first focusing grid 52 is bored with three openings aligned with three electron beam paths. The second focusing grid 53 is bored, like the first focusing grid 52, with three openings aligned with three electron beam paths, and further fitted with a shield cup 57. The third focusing grid 54 is formed of an inner annular auxiliary electrode 55 disposed substantially halfway between the first and second focusing grids 52, 53 along an electron beam path and an outer annular auxiliary electrode 56 positioned coaxially with the inner annular auxiliary electrode 55 spatially to surround it. The inner annular auxiliary electrode 55 is not externally impressed with voltage. The outer annular auxiliary electrode 56 is set at a grounding potential. With the focusing means of the above-mentioned construction, the potential of the inner annular auxiliary electrode 55 is substantially defined by an electrostatic capacity generated between the first and second focusing grids 52, 53 and an electrostatic capacity produced between the inner annular auxiliary electrode 55 and outer annular auxiliary electrode 56.
The foregoing description relates to the case where this invention was applied to a uni-potential type electron gun. There will now be described by reference to FIG. 6 the case where the invention is applied to a bi-potential type electron gun. The electron gun of FIG. 6 comprises a cathode 60, first grid 61, second grid 62, first focusing grid 63 and second focusing grid 64 which are arranged in the order mentioned as counted from the cathode side, and each bored with one opening aligned with a common electron beam path. The first focusing grid 63 is formed of at least three electrodes, namely, first electrode 65, second electrode 66 and third electrode 67. With a bi-potential type electron gun constructed as described above, the second focusing grid 64 is applied with the final electron beam-accelating voltage (for example, 25 kv) of a picture tube. The second grid 62 is generally applied with voltage of about 500 v. With the ordinary bi-potential type electron gun, the first focusing grid 63 is applied with voltage of 3 to 4 kv. With a bi-potential type electron gun embodying this invention, however, it is only necessary to impress low voltage of, for example, 500 v or grounding voltage on the second electrode 66 and connect together the first and third electrodes 65, 67 disposed on both sides of the second electrode 66 with the same potential. Namely, the first and third electrodes 65, 67 are not externally impressed with any voltage. The potential of the mutually connected first and third electrodes 65, 67 is defined by the potentials of the second focusing grid 64, second electrode 66 and second grid 62 and the capacitances C 1 , C 2 , C 3 , C 4 generated between the respective electrodes (FIG. 6). The interelectrode distance is determined by the similar method to the aforementioned embodiment. Since the capacitances C 1 to C 4 vary with the shape of the corresponding electrodes, it should be defined with said variation taken into account.
With the bi-potential type electron gun of FIG. 6 embodying this invention, a sort of uni-potential electrostatic lens is formed in the first focusing grid 63. Therefore, electron beams are subjected to a certain degree of focusing while passing through the openings of the first focusing grid 63, thereby improving the focusing property of the bi-potential type electron gun of FIG. 6 over that of a similar type of electron gun in which the above-mentioned uni-potential electrostatic lens is not produced. Unless required, it is obviously possible to change that portion of the first focusing grid 63 in which the above-mentioned uni-potential electrostatic lens is produced into such shape as prevents electron beams from being focusing.
As described above, this invention makes it possible to elevate electron lens-forming voltage whose level has hitherto been subject to certain limitations due to requirements associated with the construction of a picture tube, thereby improving the function of the electron lens.
Namely, with the electron gun of this invention, high electrode voltage is indeed applied to increase the performance of an electron lens. To this end, however, much lower voltage has only to be externally applied, thereby eliminating arcings at the base portion of a picture tube which have hitherto raised problems. Further advantages of the invention are that since an external power source need

The first embodiment relates to a uni-potential type electron gun provided with three in-line cathodes. The second embodiment relates to a bi-potential type electron gun comprising a single cathode. Obviously the type of electron gun and that of cathode can be freely combined. The point is that this invention is applicable to any type of electron gun, provided the focusing electrode or grid can be used as a capacitor type. With the foregoing embodiments, electrodes aligned with electron beam paths were utilized as the capacitor electrodes. However, application of this invention need not be limited to such type of electron gun. Namely, the electron gun of, for example, FIG. 2 may comprise a second cylindrical electrode which encloses a fourth grid and is bored with three openings aligned with three electron beam paths. In this case, an electron lens has its inner diameter reduced. Therefore, the electron lens should be constructed in consideration of the result of comparison between the effect of the voltage supplied thereto and the effect of the inner diameter thereof. Obviously, this invention is applicable to a tri-potential type electron gun.
Toshiba, "Blackstripe Vertical Stripe Screen Colour Picture Tube", 1973.
Claims:
I
claim: 1. In a cathode ray tube including a faceplate and a shadow mask
containing an array of vertically oriented slotted apertures for
restricting electron beams directed there through to impinge upon and
excite selected areas of phosphor material on said faceplate, a viewing
screen comprising:
a
horizontally repetitive pattern of sets of three vertically oriented
stripes of phosphor material extending vertically across and coating the
inside surface of said faceplate, each stripe within a set being of
different phosphor material so as to emit a different color when excited
by the corresponding one of the three electron beams passing through
the associated aperture in said shadow mask, and
a
layer of light absorbing material coating the inside surface of said
faceplate and containing a vertical and horizontal array of vertically
oriented slotted openings, said stripes and openings being juxtaposed so
that said openings define viewable portions of said stripes, each
viewable portion being totally surrounded with light absorbing material,
said
openings and stripes being aligned with the apertures in said shadow
mask so that a corresponding one of said three electron beams is allowed
to impinge upon each viewable portion,
the
vertical dimension of each opening being greater than the vertical
dimension of that part of said viewable portion excited by the electron
beam impinging thereupon, such that a positive vertical guardband is
provided, and
the
horizontal dimension of each opening being less than the horizontal
dimension of the impinging electron beam, such that a negative
horizontal guardband is provided.
2.
In a cathode ray tube including a faceplate and a shadow mask
containing an array of vertically oriented slotted apertures for
restricting electron beams directed therethrough to impinge upon and
excite selected areas of phosphor material on said faceplate, a viewing
screen comprising:
a
series of vertically oriented stripes of phosphor material extending
across and coating the inside surface of said faceplate, the phosphor
material of horizontally successive stripes differing in a repetitive
pattern so as to emit different colors within each pattern when excited
by electron beams, and
a
layer of light absorbing material coating the inside surface of said
faceplate in the form of a matrix comprising vertical stripes of
material interposed between the phosphor stripes and horizontal spans of
material crossing said phosphor stripes,
the vertical stripes and horizontal spans of light absorbing material defining the viewable portions of said phosphor stripes,
the
vertical dimension of said horizontal spans being less than or equal to
the vertical region of each phosphor stripe between vertically adjacent
beam landings not excited by said electron beams, such that a zero to
positive vertical guardband is provided for each viewable portion,
the
horizontal dimension of the vertical stripes of light absorbing
material being greater than the horizontal separation between
horizontally adjacent phosphor stripes, such that a negative horizontal
guardband is provided for each viewable portion.
3.
In a cathode ray tube including a faceplace and a shadow mask
containing an array of vertically oriented slotted apertures for
restricting electron beams directed therethrough to land upon and excite
selected areas of phosphor materials on said faceplate, a viewing
screen comprising:
a
layer of light absorbing material coating the inside surface of said
faceplate and comprising a web containing an array of vertically
oriented slotted openings therein, there being a unique set of three
horizontally spaced openings for each aperture of said shadow mask
aligned to receive the electron beams passing through said aperture, and
a
layer of phosphor material coated on the inside surface of said
faceplate within the boundaries of said openings, there being a
different phosphor material for each of the openings of a set so as to
emit a different color when excited by the electron beam impinging
thereupon,
the
height of said web between vertically adjacent sets of openings being
less than or equal to the vertical distance between vertically adjacent
beam landings to provide a zero to positive vertical guardband for each
phosphor area,
the
width of said web between horizontally adjacent openings being greater
than the horizontal distance between horizontally adjacent beam landings
to provide a negative horizontal guardband for each phosphor area.
Description:
This
invention relates to cathode ray tube screens, and more particularly to
black matrix screens for color television picture tubes employing
slotted aperture masks and a process for fabricating such screens.
Manufacturers
of cathode ray tubes of the color television picture tube type have
recently begun employing aperture masks having slotted apertures instead
of the more conventional circular apertures in order to achieve greater
electron beam transmission through the mask, since an array of slots in
an aperture mask allows the mask geometrically to be fabricated with
more total open area than the same size mask containing round or
circular apertures. The slotted apertures are typically arranged in
vertical columns on the mask, each column being comprised of a plurality
of slotted apertures. Since more electrons can impinge on the phosphor
regions of the screen in a tube of this type than of the circular
aperture, mask type, a brighter picture results. Unlike the
circularly-configured phosphor regions on the screen of a tube employing
an aperture mask having circular apertures, however, the phosphor
regions on the screen of a tube employing an aperture mask having
slotted apertures are formed in a pattern of adjacent vertical stripes,
typically with each stripe running continuously from the top of the
screen to the bottom.
Black
matrix tubes have also become widely popular as of late, both in
circular aperture mask tubes and slotted aperture mask tubes. As seen
from the viewing side of the screen of circular aperture mask tubes, the
black matrix material completely surrounds each circular phosphor dot,
serving to improve image contrast by absorbing ambient light that might
otherwise be reflected by the screen. Also as seen from the viewing side
of the screen of slotted aperture mask tubes, each vertical phosphor
stripe is separated from the adjacent vertical phosphor stripe by a
stripe of black matrix material running from the bottom to the top of
the screen.
In
fabricating screens for conventional slotted aperture mask tubes of the
black matrix type, a photoresist material coated over the inside
surface of a tube faceplate is exposed in a so-called lighthouse to
actinic radiation in a pattern corresponding to the pattern of matrix
openings ultimately to be formed on the screen. This radiation is
transmitted through the slotted apertures in the mask before impinging
on the photoresist material. The actinic light source used in this
fabrication process is linearly-elongated in a direction parallel to the
columns of slots in the aperture mask in order to permit the black
matrix material to be formed with a pattern of vertically and
horizontally-aligned, vertically-oriented slots extending between the
top and bottom of the screen. The phosphor stripes are thereafter
deposited so that phosphor of a predetermined color emission
characteristic, respectively, is deposited on the faceplate through a
predetermined slot, respectively. Three different phosphor materials are
conventionally deposited in a horizontally-repetitive pattern.
When
a screen formed in the aforementioned manner is operated in a color
television picture tube, parts of each of the phosphor stripes are not
excited by the electron beams, since electrons are blocked by the webs
of the mask between vertically-adjacent slots. These parts of the
stripes, therefore, are essentially useless in producing images, since
they provide no illumination on the face of the tube as a result of
direct bombardment by primary electrons. Moreover, the phosphor material
in these regions adds to overall reflectivity of the screen and hence
has a deleterious effect on image contrast. To overcome this problem,
the present invention contemplates substituting black matrix material to
be seen from the viewing side of the screen to avoid reflection from
the parts of the phosphor stripes not excited by the electron beams.
This may be accomplished by using a source of actinic radiation for
producing slotted openings in the black matrix material that is of
shorter length than the linear source of actinic radiation for producing
the phosphor stripes. The resulting increase in area of black matrix
material serves to reduce screen reflectivity and enhance contrast of
the displayed images. Moreover, by controlling vertical size of the mask
webs between vertically-adjacent openings in the black matrix material,
either a positive guardband or negative guardband mode of operation in
the vertical direction may be achieved.
Accordingly,
one object of the invention is to provide a new and improved color
television picture tube of the black matrix type exhibiting reduced
screen reflectivity and enhanced image contrast.
Another
object is to provide a color television picture tube of the slotted
aperture mask type having a screen, as seen from the viewing side,
formed of a plurality of vertically-oriented linear phosphor regions
completely surrounded by black matrix material.
Another
object is to provide a black matrix color television picture tube of
the slotted aperture mask type capable of operating in a positive or
negative guardband mode of operation in the vertical direction.
A
further object is to provide a black matrix color television picture
tube wherein the vertical guardband of the matrix is controlled to
enhance image contrast without reducing image brightness.
Another
object is to provide a method of fabricating a color television picture
tube of the black matrix type wherein exposures to different levels of
actinic radiation are employed sequentially in forming the picture tube
screen.
In
accordance with another preferred embodiment of the invention, a method
of forming on the faceplate of a cathode ray tube a viewing screen for a
high contrast color television picture tube of the slotted aperture
mask, black matrix type is described. The method comprises forming a
first layer of photosensitive material on the inside surface of the
faceplate and exposing the photosensitive material to actinic radiation
through slotted apertures in the mask from a first linear radiation
source of predetermined dimension along its longitudinal axis. The
longitudinal axis of the first source is maintained substantially
parallel to the longitudinal axis of the slotted apertures. The
unexposed regions of the first layer of photosensitive material are then
removed, and a layer of black matrix material is formed atop the first
layer of photosensitive material and the inside surface of the
faceplate. The exposed regions of the first layer of photosensitive
material and the black matrix material coated thereon are next removed,
leaving openings in the black matrix material. A second layer of
photosensitive material is formed atop the black matrix material coated
on the inside surface of the faceplate and atop the exposed portions of
the inside surface of the faceplate. The second layer of photosensitive
material carries a phosphor material either coated thereon or mixed
therein, emitting a characteristic color of light when excited by
electrons. This is followed by exposing the second layer of
photosensitive material to actinic radiation through the slotted
apertures from a second linear radiation source of dimension along its
longitudinal axis exceeding the predetermined dimension, the
longitudinal axis of the second source also being substantially parallel
to the longitudinal axis of the slotted apertures. The unexposed
regions of the second layer of photosensitive material are then removed.
In this fashion, phosphor material is applied over the inside surface
of the faceplate in registry with the openings in the black matrix
layer. If desired, the phosphor material may be applied in the form of
vertical stripes extending between the top and bottom of the screen by
increasing the length of the second radiation source, increasing the
duration of exposure therefrom, or a combination of both !
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