DE2027533C - Luminescent screen for a color display tube and process for the production thereof - Google Patents

Description

The invention relates to a luminescent screen for a color display tube, consisting of a substrate, the door is practically permeable to all light wavelengths in the visible spectrum, several Groups of image elements arranged in a pattern on this substrate, the elements each of these groups can be excited so that they can emit light of a corresponding primary color, and a light attenuator surrounding the picture elements of each of these groups and a method for Manufacture of such a fluorescent screen.

Such phosphor screens are known and although its principle is generally applicable, it is particularly suitable for the production of color tubes in which the Lcuchtstoftablagerungselemente must have a smaller size than the transparent parts LV color selection electrode, which is typically present in such tubes doit particular. Where the tube is a three-color shadow mask with fluorescent material wrung out in the form of spots which are arranged to represent a multiplicity of spot tri.ids, the fluorescent spots must be smaller than the openings in the shadow mask be when the R. hears either a post-acceleration focused: i'g or a black border used.

Post-acceleration focusing has the novelty that more electrons hit the fluorescent elements of the grid than usual and that this increases the brightness. the M'nvarze border, on the other hand, is a term used to denote a color tube, in that of the fluorescent substance deposition elements of e'iiL-m pigment or a light-absorbing substance ic: ml, for example manganese dioxide, are surrounded. By using a limiting, light absorbing material is the contrast of the picture-K-hre and there is the further advantage that the use of an implosion platform filter type or a darkened implosion plate, generally available in commercially available l'arbfernsehtmpfangengeräte is used, partially or becomes completely superfluous. This property of the black border makes the 1 lie of the tube increased significantly.

Some difficulties are encountered in making the fluorescent screen of a color tube to achieve Phosphor elements that are smaller in size than the transparent areas of the color selection electrode have occurred. The problem is generally the same regardless of whether the fluorescent elements are round or have the shape of strips, such as those caused by electrodes with circular openings or slotted openings are formed. Currently are preferred Use fluorescent patches and accordingly the following description is based on the assumption that that the tube in the process should have a fluorescent screen of the mosaic type made up of stain riads is formed, which are arranged over the entire image area Sn. Of course, each includes such triad a patch of a green, a patch of a blue and a patch of a red fluorescent.

The usual methods of making the leucine screen of such a tube are that on the image area is coated with a photosensitive material that is coated with actinic Radiation is selectively exposed through the shadow mask.

An obvious advantage of exposure through the shadow mask, which is ultimately considered a component of the tube in service, is that it establishes the correct positions of the phosphor deposits on the grid with respect to the apertures of the shadow mask. In general, it can be expected that the surface elements of the grid exposed through the shadow mask have the same shape and at least approximately the same size as the holes in the mask through which the exposing radiation passes. Accordingly, in an effort to make the phosphor deposits smaller in size than the openings of the mask, it has been proposed ^; To reduce the size of openings in the mask temporarily by means of a filler or by a covering made of a material which can easily be removed after the mask with its temporarily reduced holes has been used for screening. For example, cropping or other tetras can be used as a filler, which can be removed again by selective etching after the raster has been completed. Experiments have shown, however, that when a temporary filler is used, problems arise with regard to the uniformity of the spot size and the spot configuration.

In a well-known process that has become technical Making it more suitable, the shadow mask is originally made with appropriately sized holes provided, which can be used for rastering, so that the luminous plug deposits the correct Diameter or the correct dimension. In this procedure, the mask is carried out after the grid is etched back to the holes to a desired size in relation to the Fluorescent stains that appear on the screen of the grid Have been knocked down to reopen cider to enlarge.

It is highly desirable to have a color cathode ray tube of the type mentioned in a process in which no further process steps for the shadow mask are required and this object is achieved by the present invention.

But now Vei are going through what oily in a grid structure with a black border that are smaller than the Opening diameter of a color selection mask, very complicated. According to today's manufacturing practice you start with a mask with small openings, whereupon all optical exposures are made with this Mask made and then the mask holes to get the necessary for use in the end tube Size can be expanded by etching. It should be noted, however, that after the mask holes once expanded by etching, the mask can no longer be reused for optical exposures is, if a grid shortage is found later. In addition, the mask is with everyone Deformation as a result of the etching process a Ti t.ih; rlust and must be thrown away.

The object of the invention is to provide a new and improved luminescent screen structure for a Specify color display tube, as well as a corresponding manufacturing process, which is particularly for Implementation of the black border and for

Tubes with post-acceleration focusing of possible wavelengths of the visible spectrum through

nel is. "Is casual. The substrate is of course the picture surface

This task is due to the in claim I or the front panel of the picture tube and it can be a

given invention and indicated in claim 6- permeability of 100% for visible light on-

bene manufacturing process solved. 5 or it can have some more filler equipment

Hierbci is particularly advantageous that the new gene have to be

Rasler no mask treatment (i.e. enlargement wedge for visible light of e.g. 90% odo

by Λι / cn) to reverberate light-emitting places less to increase the contrast. From the standpoint!

that is smaller than the holes of the paints from the material it is about

election mask are. The inventively claimed a known glass assembly which is usually

Process makes the technical process to the wise for the production of the envelope of a color

Image enlargement by means of half-shell exposure is used for the cathode ray tube, for the materia!

need. The Iront plate does not require any special features.

If a grid deficiency is discovered, the number of groups of image clusters can be

Mask can be used again, as there are no un- 15 in a superimposed pattern over the

reversible masking has taken place. Substrate 10 arranged, the elements eachdic-

The scr groups obtained with overlapping filters can be excited so that they light a

Finally, the raster has a lower reflection-determined primary color than a corresponding one

degree than that in U.S. Patent 3,146,368 bc- emit a multitude of primary colors. This picture·

schricbenc razor construction for black borders. 20 elements are deposits of various leucine

In addition, the individual filter sections lead to fuel materials. the colorimetrically so on top of each other

reflectance lower than unfiltered, so that they result in the formation of Weil

rich. Thus, the lower reflectance designs add up. In a usual 3-color picture like you

the manufacture of a tube with superior Kon- gabcaddl.bnssyslcm, as it is usually technic π

touch. since the basic color is used depending on the choice of 25, the primary colors are green, blue.

anechoic fluorescent emission and the filter and red used and the corresponding leucine

absorption properties is approximately the same. Substance deposits are indicated by the letters G. Ii

Further developments are indicated in the Untcransprüchcn gc- and Ii in the drawing. From the Darste!

indicates. I can see that each of these I cuchl-

The invention is in the following in connection with sloffablagcrungcn approximately the form of a Fk \ ki-s ] ·, -. <1.

explained in more detail with the drawing. although they specifically have a 6-sided pointed arch shape -

Fig. 1 represents a plan view of a represents according to the manner in which its

Part of the screen of a color display figure is limited, as explained below wi: »l tube. the crfindungsgemaß is built. If the tube is a perforated mask

Fig. 2 shows a section along the line 2-2 35 tube acts in which the Farbsclektionselcktrode chk

1. Mask with a field of circular openings d; n

As already mentioned above, if the applicability is, it can be said that this

the invention regardless of whether the grid from rungsclemcntc (7, B and R at least in the first vicinity

Lcuchtstoffelcmcnten was produced, which generally have a configuration that in general

are generally circular or whether this shape is the same as the openings of the mask. D;

of stripes have; for reasons of expediency, their location on the grid and their specific design

however, the one that is customary today consists of exposure of the image area with actinic

Raster type described by IHcckcn triads. Be it radiation or clinical energy through the opening

also noted that the shape of the tube results from the mask, each group is the image

has no special meaning. The invention consists of 45 elements, be it green deposits

both on tubes with round and on tubes with blue or red fluorescent material, across the image surface

Can be used with rectangular image areas. In each in the same pattern as the pattern of the openings

In the case of the case, the housing consists of two connector sections distributed in the perforated mask. In addition, sine

th that. as usual with the grids, originally the respective positions of the Bfldelemente of the drc are separated from each other. One of these sections 50 groups by the position of the source of the actini

hereinafter referred to as the front panel section see energy in each of the three exposure levels in

net, which is determined in the same way from the image area and an essential element surrounding it

the edge (flange) consists. The other section is as in conventional Photorcsist slurry grids

conical and is designed and on its broad method for the deposition of oil specks on the outside

Find dimensioned so that it fits onto the flange of the 55 a mosaic grid of the type in question. Although the

Front panel fits so that it is finally by tapping three pixels of the picture elements according to the

Frying crimps or any other like pattern lie out of these

Appropriate joining method, basically joining the patterns in between on top of one another

which can be. The smaller end of the conical substrate and limit together the one you want see Alischnittcs ends in a throat that has a 60 multiplicity of the square triads. Such a triad

Arrangement or a group of three cathodes - is for example by the digits 11g, II around II /

Strahlcr7cugern enveloped. The tube structure can. shown in FIG. Another feature dci

Apart from its grid and the method of image elements, there is in particular the fact that every

Let the grid be a common structure and these elements have a basic dimension that is not explained in detail below. H is the corresponding dimension for E! Ectn>

The properties of the grid are shown in FIGS. In a transparent hatch or in the color

URtI 2 explains that a section nus a sub- sclcllinnvlrkirndc Sn Kt, for example, the maxi

suat IO / eigen, which essentially stands for light, including the entire dimension of the picture element II ρ ocrineer ah

,,. .,. ", _M _". _w "ι? from the one

dcr hole diameter 12 * ^ r mask 'J 12 n ° Jerj.n

Partial section in the ^F "8 ^ ^d er ^ U.ll ^ isl _; To« nc

unnecessary confusion in the figure. I too was not shown the _{make_auS} . If the I ^ hmaske ¹ J Jr development with respect to the image surface 10 nchüß g net, the M "kc s.nd" locher12 α on cmc be agreed Tnade ausgench et at P ^ ^CIS ^ J | { "* and Mr. .ImNormalfallc has d.eRoh * dr ^«K Atho denstrahlerzeuger on, each of which-a ^ UCR tronenstrahl * jfljn through the holes ^d" ™ "ke ^a grid 10 aligned and the angular arrangement de_Srah ^ len to the mask is such that a beam only au green Bildelemcnt G ι another just because. Waue image element B and the drille ™ ™ | ^d "Jf ^ JJ, element R auftnfft. For the M ^'11 ^^^^? ⁸ ^ this angular relationship is ensured by the geometry: the cathode emitter groupc_ and O'

Such relation becomes ^au i ^rcch ^ ^a S ray under the action of a y

Verg-nzsystem (not shown) that doesn’t have to be, as it is a building_a _

that are known on the ueDiei uci ^l ? '"""£"' ~~:? ~] λ.: ~ stripes across the mask and the grid.

A desired property of the picture elements as required for a raster of the post-acceleration or black border type has already been explained. This then means that the effective area of the fluorescent deposition belt is smaller than the area of the perforators on the locating mask. The expression »effective surface of the ueuem-

Substance deposition element means that only no contributes to the phosphorus ^{deposition to d} = ^ P ^IId ^ ^ede ^ Pl [ . Obviously, a deposit that is superimposed on a device for the .P visible light is ineffective generation of an image and can become »« ^ «™. Another property that is required when the grid is to have a black frame is a weakening device. lengths of visible light, which on the lenra10 grids or the substrate ang ^ ra ^ is ^ wetehe ^ different picture elements each

of the elements "" ^^. ^^^ " _ρ ^ε ^ Τ! ρίΐ 1 facility is indicated by the ^ hatching in ^ oerτι ^, weliAeclasBilddmentllguin ^ dargesieul ·

probably the hatching for the purpose of ^ n

Elevation only for this "individual Ue"

is, of course, it is clear that ^d t

Grid with a similar ^

for visible loves provided smd.

facility consists of. ^ - V ^

the individually one proportionately one of the best for light

and a relatively low one

light for the rest of the visible

simply by the m the ^ Vg. 1 ^> ™ "which defines the Tefle of substrates * ^^ ™ _Faile Büdelemente surrounded unöinem ^^ durchlaskann the ^s" ^ "FTIR ^ e ™ n ^ n

^^ ÄSin s-line emits the color that that particular element to-^ _{crläu (Erten Fa "insbcsordcrc} g _{Eicment würdc n} ^ _is ^. _{Dcf LcudUslo {T.}

deposit simply _r around a green fluorescent ■ J J _{dci bckanntcn} composition act, t, has _gewünschlcn Fnrbkoordinaten. _E rfindun _e convention under but _vcremfachim a large Arbcits | _cr2ic | _t by creating a special

_other n construction used in which each of the filters - "^. ^ _dne , _{en Bildclemcnl}

^ ", _{Nct is and is} over the part of the substrate 8 of _{each image | cmcnt of scincn neighbors}

_so ^ _{djese in} ^ _way ^ _KompQ .

represent overlapping filter of the Lichlschwä _{chungscinrichtung} . This is shown in Fig. 2B, in which the filter component of the

green Bildclemente * 11 g is denoted by 13g. You 8. _{rf directly} ^ _{the substrate % Q a || f brachl and dcr}

_{Leuchtsloff c is in} turn layered over its to | ^ filter component 13g. The diameter of the Fillerkomponentc 13g überocschrei _t et clearly the maximum dimension of the phosphor _{G un (J dicFillClkomponente} extends ^ ^ _djc ^^ ^ _Bi , _de , _{emcntcs G addition}

_a . In a similar manner, a blue _{filter 5 is shown in FIG} . _after application

¹ _{has been} fi _rü nfilterkomponentc 13g _applied to the substrate 10th As a result, the part 13 b 'of the blue filter component is _{superimposed on the corresponding peripheral area of the green} filter component 13 g. on

. ^^^ _{Wejse weisl the red} filter component 13 r _{cinen Randtdl l3} / _{aufi dcr s} j _c h extends over the adjoining ^ _n ^ _{the green filter component} 13 g. _υ ^ ^ _{Assumption that the RotfiUcr as Ictztcs the}

has been applied. are, it has a further _Randtei f ₁₃ ^ _{on, dcr ci} nenTeü 13 ö "of the Blaise nlter _{fcom te} superimposed. These overlapping _{Randtei] e of F,} u _e rkomponenten by the hatching in F i g. 1. If the FiI-terkomponenten in a correct colorimetric

Relation to one another is every part of the Ra- ^^ _{JQ fa dem two or more such FiUer over} rfappen, practically black, ie every part white ^ _a {j _{extremely low} permeability in de. _{Proximity of 10} to 20 »Ό or less for all waves- ^^. ^ ^ _{Visible spectrum} .

^ _yQrestanding (^^ "^" 6 grid structure is functionally similar to the structure known from the US patent 3146 368, in stnik however, completely different from this in a turcller respect. Ii _the j ^^^ _{Aufljau bestfM each picture element au fa} phosphor deposit, which is surrounded by a light-absorbing pigment, while in the construction according to the specification the light attenuation i:

SS the area between the Büdelemente durcl a visible light attenuator is provided which surrounds each picture element overlapping filters, which individually a vei sustained high transmittance for light from a medium

*, agreed to assigned primary color, but a low red transparency for light from the rest of the eyes have available spectrum.

^ Matcriaüen for the different Füterkon components are, for example, those suitable, ie

_6s ^ _da USA.-Patentsrhrift 3 114065 are described and they can be inflated according to a process ^ d * s dew hi of USA.-Patent 2,95? 48 claimed procedures »corresponds to especially *

309621/3!

10

net for use as filter components are mixed and separate areas of the Color filter glass materials having a relatively grid with the same pattern arrangement as that low melting temperature on the order of holes in the mask. It is known that the of 430 ° C, which are commercially available. Particularly the diameter of each exposed area due to the fact that glasses with a thermal expansion intensity of the light and the duration of the exposure coefficient are suitable, which is equal to the expansion interval can be controlled. These parameters coefficient of the tube piston material; these are set so that the latent To achieve the required image of the green filter components, glasses are those shown in FIG. 1 Color filter properties of inorganic dyes, size shown by the dashed line, puts. As a dye for the blue filter components io this image is then developed by making the can for example cobalt oxide, for green can copper substrate 10 washes with water to complete ferrous oxide or chromium oxide and for red cadmi- der can form the group of green filter components sulphide can be used. Glasses of this type are 13 # on the substrate 10. The individual green filters are advantageous because, as is known, with high vacuum catho components they actually have the shape of a the beam tubes are compatible. In addition, 15 projection of the hole aligned on them can They are made by collotype and electrostatic processes, shadow mask and they are round as one is present in the present As the case for the deposition of fluorescent substances is based on the assumption that the Color materials used method, on the mask has circular openings 12 a. Surface of the substrate 10 are applied. Your A similar sequence of stages will be for each of the others

low melting temperatures allow the ao groups of color filter components to be carried out. Fixing the filter components on the substrate The only changes required for the production of the blue filter components in the course of normal tube processing, th 13 b , consist of using a photosensitive resist material without the need for special processing temperatures, in which the phosphor deposits are the one Powdered blue filter material could be damaged. 25 digit of the green filter material and that the

The methods described in U.S. Pat. No. 2,959,483, aligning the light source for exposure, generally have to be modified for screening to be suitable for use with the cathodes used to excite the structure of FIG. 1, although certain of the blue picture elements are provided In the production of the red raster according to the invention, not only one filter component 30, color filter components 13 r , the photoresist and an overlying fluorescent component contain a red filter additive and the light, which together contain a red filter additive The picture element as in the source is attached in such a way that it delimits the catho-filter component provided for the Er-ÜSA.-Patent 2,959,483, but the excitation of the red picture elements also extends simulated into the jet generator.

the space surrounding its pictorial element and works. In this stage of treatment, the grid has three itself patterns of green, blue and red superimposed on similar extensions of the filter components of the neighboring picture elements together and these color filter components, their outer peripheral areas put so the light attenuation or the black overlap and an attenuation device Define border for visible light, which the image surface

Also the slurry grid with a light element surrounding the substrate 10 and each of these sensitive resist material, which contains a filter material area covered by a single color filter, in powder form, is a suitable method. that essentially only transmits the color or wavelength A useful slurry consists of one of the light for which it is intended. It is organic light-sensitive material, which is normally only necessary to apply the green, blue and red sometimes soluble in water, for example with 45 fluorescent deposits on their assigned ammonium dichromate sensitized polyvinyl alcohols, each of which is hol. When such a slurry contains a green filter phosphor deposit deposited on an associated and colo of powdered fusible material, rimetrically related filter component, it can be in the usual manner in the form of a. Any color phosphor can be applied to virtually the entire substrate 10 with the coating. 5 »same stages as they are used to manufacture the filter. As a result, the surface of the substrate components are used, which are placed in a state that they can be exposed to the. The only significant difference concerns that with actinic energy, for example ultraviolet exposure interval, assuming that the light can be altered. In the next step, the light source will have practically the same intensity for all driving steps, the shadow mask 12 will have its correct exposure levels arranged, in this case the surface of the phosphor deposit that it is the cathode ray generator of the tube simu- lar to that of its associated filter component. liert, because-.u determined, the green disc elements This is however not necessary and it can be a shortening or the phosphor deposits to excite. The ultra- &> zere exposure time is used because there is only violet light of the energy source, which is then required that the phosphor on the inner openings 12 a of the shadow mask 12 for selective exposure of the associated filter component Iichtung the coating of the substrate If is steered and deposited. It is clear from this that one thereby creates a latent image in the group of the desired tolerance with respect to the screening of the green filter components. This exposure is made ⁶ 5 phosphor materials. As long as the minimum is reached naturally in an exposure chamber or in a light spot size, no disadvantageous light housing and the exposed parts of the polyvinyl effects are to be feared if the deposits are alcohol-coated in a group of circular shapes beyond the limits of the image element

11 12

Schwiichungseinrichlung extends, simply because of that, partially selectively exposed. If the for

because the attenuator used the light under developing the latent image

suppressed, that of the powder of parts within that range both powdered filter material as well as

the attenuator for visible light contains ab-shaped phosphor material in suspension,

stored phosphor could be emitted. 5 oeide sit down together and they become

After the phosphor deposits have been produced, they are simultaneously in the discharged areas of the grid

the grid can be deposited in the usual way with a. The desired stratification can

Film and an aluminum layer can still be obtained if the filter and luminous

and the filter components become fabric materials of suitable relative densities to one another on the substrate

10 have by melting either in a separate io. For example, if the filter consists of a

Heat treatment stage or material that is difficult to burn out, for example lead glass, is produced

nens fixed. it will settle first and the phosphor will

The grid structure according to FIG. I can also then, as preferred, be deposited on the filter,
electrostatic grid processes are processed. It is not necessary for the toner to carry out both the filter material and the fluorescent materials at the same time as a substrate 10 first with a coating. For example, after a latent image has been provided with a conductive material, onto which a photoconductor layer is exposed by exposing the previously charged photoconductor layer, which means that the filter material can be organic matter in both cases Toner applied and the excess can act to avoid burning out. The * ° to be poured off when the filter material is deposited. The grid is then subjected to a corona discharge. Sufficient residual charge remains on the photoconductor to generate an even charge on the entire photoconductor so that a second toner can now be applied. At this point, the person carrying the phosphor material, which then exposes the grid through the shadow mask to ultraviolet light to form the desired layer formation, is deposited around a latent charge image of the filter material. This has the green filter components to produce and this image has the advantage that both the filter material and that are developed by applying a phosphor material to a group of image elements polarized by toner on the image surface, which fusible green can be applied without the photoconductor. _{Contains η (:%} ρ: | t crnia i _Cr i _a ) in powdered form. The ter has to be recharged. In this case the polarity of the toner depends on whether a direct 30, however, the filter and phosphor components image or If a group of the picture elements is completely removed - assuming that each exposed area is discharged, the picture elements of the remaining groups and the filter material on the discharged area are generated in a corresponding manner. If the toner is driven with the same polarity, it is faster than the verrity described first as the charge of the photoconductor is provided drive it 35, in which the three groups of filing compo is referred to as reverse image making. The harvest is first applied and then the three groups generating a direct image occurs when the phosphor components are deposited. Polarity of the toner opposite to that. According to another variant of the method, the charge of the photoconductor can be, in which a toner with a filter for developing the trap of the toner from the parts of the photoconductor 40 latent image of a group of filter components is attracted the exposure can still be poured over the image area and have after the charge. · The compositions of the deposit of the filter material can be applied to the fluorescent, electrically conductive and photoconductive layers, material of the appropriate color that are required for the substrate, are preferred by adding it For example, the toner is characterized by the fact that it sprays from organic 45, so that it is thereby deposited and on top: if the material is made up and its corresponding filter component is deposited during the burnout,
can be easily removed. In any of the electrostatic screening processes, the light pulse is deposited directly over its associated component to deposit each of the filter cords and then each of the light filters is deposited without the photoconductor components being carried out, 50 layers being performed in each is recharged again, the filter and trap have the position of the light source, the exposure phosphor components the same size in the interval and the additives and the polarity of the toner in contrast to the illustration in FIG. 2, in which must be taken into account. In this respect, the phosphor component G, for example, with a small screen process, is very similar to that described above than its filter component 13 g. In such a process using a sensitized trap, the overlapping filter particles are superimposed on polyvinyl alcohol. When the three sets of filter components 13 b 'and 13 / of the aneindergrenzenden components one after the other and subse- picture elements and their fluorescent components Bend, the phosphor components Open phosphor component G sequentially and their Filterkompogetragen, the photoconductive component 13 must, of course g. Those filter and phosphor component layers after each of these different components have been applied, which for example overlay the phosphor components filter and phosphor components G again, preferably have such a charge. However, certain simplifications are possible in the electrostatic screening of thickness in relation to electron speed. of those encountered during the operation of the tube

For example, it is possible to use the filter and electron scanning beams so that they encounter the

Txnichtstoflteile at the same time on a group 6 _S brake the electrons so that they do not get into the

of picture surface elements to apply, fluorescent component G in advance at a speed

assumes that the photoconductor penetrates to generate a latent which is sufficient to excite them. When

Charge pattern in the group of green filter compo- this is not the case, the area of the example

13 I 14

have the grid 13 g surrounding the image element G, each image area element consists of a filter component

the tendency to emit green light instead of in the and an overlying and colorimetrically enl-

desired way as a weakening device for speaking phosphorus component with the same

visible light to act. Expansion like their filter component consists of that

In the foregoing, the electrostatic grid 5 is not, however, overlapped with the neighboring elements.

Including the photographic process under laps.

Exposure to ultraviolet light creates each of the groups of filter components

of a latent charge image has been described, it is preferably a continuous coating on the

however, analogous results can be obtained represent corresponding picture elements of the substrate IO,

however, by scanning a slice of one onto the image this is not a necessary limitation of the

surface applied organic insulating mate structure. If the filter component is discontinuic

rial with an electron beam that is borrowed from the gecigne-, for example, has a crystalline form,

The simulated color center is localized and still satisfactory results are achieved,

walk to the image area only through the openings or if there is a sufficient overlap of the crystals of the

The electron-transparent parts of the color electrolyte 15 different filter components to achieve the

tion electrode has. Such a method allows the desired attenuation of the visible light in

also the convenient production of the desired parts of the substrate is present, which the multi

rclative sizes of the exposed surface elements surround the plicity of the image surface elements,

of the grid and the openings of the color selection- A particular advantage of the present invention

electrode. 20 is that it is no longer necessary that

This simultaneous storage of filter material size of the mask holes either for adaptation

and fluorescent material, simultaneously in the sense of rasterizing or after rasterization is complete

that both materials change to develop a single one. In the method according to the invention

latent charge image are used, regardless of the grid with its openings of the desired

gig of whether they are together or one after the other 25th final size for use as a color selection

be applied, was described before the electrode was made of the ready-to-use tube. this

Background of a type of color cathode ray tube is a great advantage in terms of uniformity

with shadow mask and black border area, where there is difficulty, the procedural complications and the

brings special advantages. This screening process is cost. Another advantage of the present invention

Of course, it is generally applicable and can, for example, consist in the filter components of the

wise to raster conventional color cathode ray tubes or the visible light attenuating device

rcn can be used. It is also necessary to create the black border at the same time as the luminous

from grids of the substance deposits mentioned in the above-mentioned patent specification can be produced, where-

3 114 065 are suitable in which the production of the grid is simplified.

1 sheet of drawings

Claims (13)

Patent claims: 1. Fluorescent screen for a color display tube, consisting of a substrate for all light wavelengths in the visible spectrum are practically transparent to several groups of picture elements arranged in a pattern on this substrate, the elements each of these groups are excitable so that they emit light of a corresponding primary color can, as well as a light weaker that surrounds the picture elements of each of these groups, thereby characterized in that the light attenuator consists of overlapping filters, the overlapping filter areas only are arranged on the substrate parts which surround the Bildelemen'e, and the filters individually one relatively high permeability for Light of only a certain primary color and a relatively low permeability for light of the rest of the visible spectrum. 2. Luminous screen according to claim I, characterized in that that the individual filters are each a component of each of these ^ Mdelemente, their Luminescent component emits light for which the associated filter has a relatively high permeability. 3. Luminous screen. ·. according to claims I and 2 for a color picture reproduction tube which has an ais Color selection corner electrode designed as a shadow mask with a hole pattern that is thru-hole for electrons, characterized in that the Shape of the individual picture elements of those of the individual permeable holes of the color selection electrode corresponds to, but the individual light-emitting picture elements are smaller than that individual permeable holes of the color selection electrode corresponding to them. 4. Luminescent screen according to claim 3, wherein the holes of the mask are substantially circular are, characterized in that the filter component between the substrate and the Leuchtstolfkoniponente and is substantially circular and has a radius approximately equal to the distance from the center of a picture element to the outer perimeter of an adjacent picture element. 5. Luminescent screen according to one of Claims 3 and 4, characterized in that it has three groups pen of picture elements, each of which is intended. Light of one of the primary colors Emit green, blue and red. 6. A method for producing the luminescent screen according to any one of claims 1 to 5, characterized in that the groups of filters are applied to the clic picture surface by coating the picture surface of the picture display tube with a material which ^{converts the O 1-} »rflüchc into a state offset that can be changed by the action of Euergie, through exposing the image area by clicking the color selection electrode from a source which is arranged so as for the purpose of exciting a specific group of the picture elements in known manner to simulate the electron gun of the picture tube in a to a to form a latent image of the filter group with a high permeability to the primary color associated with the exposed group of surface elements, develop the latent image to form the filter group, and carry out the steps described above for each primary color. 7. The method according to claim 6, characterized in that the image area with an organic photosensitive material is coated and that the coating has actinic energy exposed to a certain intensity for a period of time to certain parts of the To expose coating that correspond in shape and size to those for a group of these Filters are desired. 8. The method according to claim 6 or 7, characterized in that the photosensitive coating contains a fusible filter material in powder form in suspension and that the coated, exposed image area is heated to melt the filter material and onto the selected Fix parts of the image area according to the exposure. 9. The method according to claim 7, wherein a photoconductor is used as the photosensitive material is, characterized in that a desired surface condition on the image area is made by evenly charging the photoconductor after coating, expose the image surface with actinic energy! becomes a latent charge image of the filter group and that the charge image is developed by placing a polar on the image area ized toner is applied, which contains the filter material in powder form. 10. The method according to claim 9, characterized in that that to apply each filter group to the image area, the phosphor material, emits the light of the primary color, for which the filter material is highly permeable, onto the filter material is applied without recharging the photoconductor. 11. The method according to claim 10, characterized in that that when applying each filter group to the image area, the fluorescent material at the same time as the filter material is applied by touching the image area after exposure applies a polarized toner that removes the filter material! and the fluorescent material in Suspension, but in such relative densities that the filter material is first on the Image area settles and that the phosphor material settles on top of the filter material. 12. The method according to claim 10, characterized in that that to apply each group of the filters to the image area after application.! of the filter material, the toner for the filter material is poured from the image area and a second polarized toner, which contains the fluorescent tube in suspension, is applied to the image area and that the phosphor settles on top of the filter material. 13. The method according to any one of claims 9 to 12, characterized in that the image is heated is to melt the filter material on the respectively selected surface elements after Exposure and development have been carried out for each filter group.