DE2264122A1 - COLOR TUBE OF THE MATRIX TYPE WITH FOCUSING - Google Patents

Description

Dr. ! no. H. MoqsfKtenic

Dipl. Ing. H. H .-. «.-;.!: - '. ic! Pbys. W. Schmitz

Dipl. Ing. E. Gra:.! I <-?;.;. Ing. V /. Wehnert

B WiiiiciCü λ, '* ■: ■ " ·, ..; - . _L _'- j2 <* 25

Telephone 53

Hitachi Limited

5-1, 1-chome, December 27, 1972

Attorney File M-2475

Matrix type color picture tube with refocusing

The invention relates to a color picture tube of the matrix type with refocusing having a front shell, one on the inner surface the front shell formed fluorescent screen including a plurality of phosphor areas, each of which is smaller than the diameter of an incident electron beam and in its gap areas a non-excitable and light-covering substance is applied, a neck, an electron beam gun arranged in the neck for the generation of the electron beam, a funnel extending between the front shell and the neck and one near the fluorescent screen arranged color selection electrode.

A strong electric field is built up between the color selection electrode and the luminescent screen, around that from the electron beam gun to focus the exiting electron beam and

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to accelerate. A part of the through the color selection electrode ^! passing electrons is reflected and another part generates secondary electrons; Reflected electrons and secondary electrons are accelerated by the strong electric field and therefore undesired phosphor areas are stimulated to glow, whereby the color unit of the reproduction to a large extent! is worsened.

To avoid this difficulty, there is already a color picture tube

i have been developed of the matrix type in which the gap areas between j

see the three-color phosphor areas making up the phosphor screen are coated with a light-blocking substance such as graphite that cannot be stimulated to glow. The diameter of the Electron beam incident to desired phosphor areas along the entire surface of the phosphor screen is made larger than the width of the phosphor areas. Because thus the area of the fluorescent screen, which is reflected by secondary electrons and Electrons can be excited to shine, is reduced, it is possible with such a color picture tube that by such Electron induced degradation in color purity.

But since it is necessary, the diameter of the electron beam on the surface of the luminescent screen is sufficiently larger than that To make the width of the phosphor areas, the width of the perforations of the color selection electrode must be made larger than that of Color picture tubes of the usual type. The enlargement of the perforation width of the color selection electrode contributes to the increase of the electron

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beam transmission ratio at. For example, the transmission ratio is for a color picture tube with a conventional shadow mask at 15 to 18%, for a color picture tube of the matrix type at 20 to 30% and a matrix type color picture tube with refocusing at 40 to 85%. With this construction, a color picture tube can be used of the matrix type with refocusing, an image with high contrast can be achieved. But since the width of the perforations is large, the mechanical strength of the color selection electrode is poor if its thickness is kept small. Hence the mechanical strength the color selection electrode of a matrix type color picture tube,

To increase with refocusing, not only the color selection has to be I

electrode have a greater thickness, but it is also preferable that the wall of the part facing the phosphor screen of each perforation has an inclination which is far greater than the inclination of the wall of the opposite portion of the perforation. In particular, to increase the mechanical strength, it is desirable that the wall of the opposite area of the perforation does not have any inclination or extends parallel to the central axis of the color picture tube. If the generation of secondary electrons is taken into account, however , the opposite wall of the perforation must be slightly inclined with respect to the center of the color selection electrode. Under these circumstances, it is desirable that the width of the perforations on the side facing the phosphor screen is made smaller than the spacing of the perforations.

In the case of a color picture tube of the matrix type with refocusing in which the width of the perforations of the color selection electrode is larger

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must be than with an ordinary color selection electrode, so must the thickness of the color selection electrode can be increased to increase its mechanical strength and the ingress of electrical Avoid field lines in the perforations of the color selection electrode. It is also possible that the perforations are inclined, to align with the deflection angle of the electron beam, thereby generating secondary electrons and reflected electrons is avoided. However, there are difficulties in this way of improving the color unity.

It is therefore the object of the present invention to provide a color picture tube of the type mentioned above, in which the mechanical strength is increased in a simple manner and the ingress of Field lines of the electric field in the perforations is avoided.

Electrons should also hit the inner wall the perforations of the color selection electrode are avoided, so that no secondary electrons and reflected electrons the inner wall can occur.

To solve the problem, the invention is based on a color picture tube of the type mentioned above, which as a result of a large number of perforations has an electron beam transmission ratio greater than 401 for the passage of the electron beam.

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The object is achieved in that each of the perforations one part facing the luminescent screen and one of the elec-! has electron beam cannon facing part and the axes of the ι both parts are offset from one another, the offset in the center of the color selection electrode being essentially zero and increases steadily towards the edge area.

The prior art and the invention will now be based on the two;

added figures are described in more detail. From the figures show ^

Fig. 1 is a schematic section through a known color picture tube with refocusing;

FIG. 2 shows an enlarged partial section through part of the color picture tube shown in FIG. 1; FIG.

3 shows enlarged partial sections to illustrate various ¹¹¹¹ embodiments of the perforations of color selection electrodes belonging to the prior art;

Fig. 5 shows a cross section through a perforation of an inventive formed color selection electrode;

FIG. 6 shows a schematic plan view of the color selection electrode of the shadow mask type shown in FIG. 5; FIG.

7 is a graph showing the upper and lower limit values the distance between the axes of the front and rear parts of the perforations of an inventive

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Color selection electrode.

The color picture tube shown in FIG. 1 and belonging to the prior art has a front shell 1, a funnel 2 and a neck 3 existing tubular body 4 from £ On the inner surface of the front plate of the front shell 1 is due to the application a fluorescent color screen 5 is formed from three phosphors. At the predetermined distance from the luminescent screen 5 is a color selection electrode 6 arranged. An electron beam gun 7 is arranged in the neck in an axially aligned manner. On the inside wall the funnel 2 is shown schematically as in Fig. 1; a conductive film 8 is applied. The refocusing device exists the color selection electrode, a frame member 9 for holding the color selection electrode, and frame support members 10, which serve to fasten the frame component 9 on the inner wall of the front shell. Between the luminescent screen 5 and the Nechfocusingeinrichtung is used to build a strong electrical Field a suitable voltage is applied between them in such a way that the exiting from the electron beam gun 7 Electron beam 11 is focused and accelerated. j

As can be seen in particular from FIG. 2, the electrode j deflected onto the edge region of the color selection electrode 6 strikes

inner beam 11 on the color selection electrode at a larger angle of incidence (£> than in the central area of the color selection electrode.

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Electrode 6 passing electron beam 11 on the wall surface the individual perforation, so that secondary electrons are generated and electrons 13 are reflected at the point of impact. There If these electrons excite undesired phosphor areas of the luminescent screen to glow, the color purity is reduced.

To solve these problems, the perforations 12 must be so designed that the following condition is met:

Ta (t - s) tan θ (1)

where T is the projection of the inclined wall surface of the individual perforation onto the surface of the color selection electrode is,

t characterizes the thickness of the color selection electrode, s the thickness of the non-inclined part of the color selection electrode characterized, and

θ is the angle of incidence of the electron beam on the color selection electrode is.

The value of T that satisfies the equation (1) is very large. There

the value T according to FIG. 4 by the distance (pi tdVJ of the perforations j

■ ι

; is limited, it is often very difficult to determine which is determined by equation (1)

j to satisfy the condition expressed.

In Fig. 5 the cross section through a perforation is one according to the invention Color selection electrode 14 shown. The axis 16 is the part of the perforation 12 facing the electron beam gun 7!

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and the axis 17 of the part of the perforation facing the luminescent screen have a distance of D from each other which increases toward the peripheral area of the color selection electrode. In other words th: The distance D between axes 16 and 17 is zero in the center of the color selection electrode and gradually increases to its edge: area to. According to one embodiment of the invention, it includes the luminescent screen formed on the inner wall of the front shell ^

several fluorescent dots and a non-excitable substance, which are placed in the gap areas between the fluorescent dots is upset. An electron beam emerging from the electron beam gun hits the phosphor dots the shadow mask type color selection electrode having a plurality of circular perforations. Gradual increase of the distance D for a color selection electrode from

in
The type of shadow mask is shown schematically in FIG. 6.

In another embodiment of the present invention the luminescent screen has a plurality of fluorescent strips and substance that can be stimulated to glow, which are in the gap areas is applied between the strips. The color selection electrode consists of a large number of strips Perforations for the passage of the electron beam, each perforation being divided with the help of bridges the fluorescent strips are formed along the vertical deflection direction, for example over the entire inner surface of the front shell, and the longitudinal direction of the strip-shaped perforations is chosen so that it coincides with the vertical deflection direction,

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is the electron beam against interference from the magnetic Earth field protected.

To improve the mechanical strength of the color selection electrode and to avoid the generation of unwanted reflection and secondary electrons. each of the strip-shaped perforations a part facing the luminescent screen and a part facing the electron beam gun on the one against the other are offset, the offset in the center of the color selection electrode is equal to zero and continuous to the edge area of the color selection electrode increases towards. Also, each of the strip-shaped perforations has in relation to the center line of the color selection electrode overhead area has an upper end which extends into a part of the bridge facing the luminescent screen, namely with gradual extension towards the edge area of the color selection electrode; at the same time, each of the strip-shaped Perforations in the with respect to the center line of the color selection electrode area below a lower end, which is

; into a part of the bridge facing the luminescent screen ! stretches, gradually extending toward the edge portion of the color selection electrode. Curves A and B of Fig. 7 show the upper and lower limits for the distance D. In the case of a 20 inch color picture tube, the relationship between the distance D and the distance r from the center of the color selection electrode are given by the following table:

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r (well) D (, u m) B. ο A. 0 50 20th 2 100 31 17th 150 42 30th 200 53 43 220 65 50 68

If the perforations 15 of the color selection electrode are designed in this way, when the electron beam is deflected towards the edge region of the color selection electrode, it will not impinge on the inner wall of the perforations 15, so that no reflected electrons occur and secondary electrons are generated. Therefore, an increase results in the distance D between the axes 16 and 17 of the front and rear portions of the holes of the perforated \ mask easy to satisfy the equation _(1); whereby the

Color purity characteristics of the color picture tube significantly improved

j will.

Although only those components of the color picture tube have been shown and described which are necessary for an understanding of the present invention are absolutely necessary, it should be understood that other elements, such as deflection coils, are also associated with the tube are. -11-

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Claims (6)

Dipl! ,,. . . . "" ·> ■; :: ^. nrutr Munich 2, tViozcr-straße 2.T efor. Hitachi Limited 5-1,1-chome, Marunouchi December 27, 1972 Chiyoda-ku, Tokyo, Japan Attorney File M-2475 Claims 1. Color picture tube of the matrix type with refocusing with a Front shell, a luminescent screen formed on the inner surface of the front shell including a large number of phosphor areas, each of which is smaller than the diameter of an incident electron beam and in their gap areas one that cannot be stimulated to shine and that covers light Substance is applied, a neck, an electron beam gun arranged in the neck for generating the electron beam, a funnel extending between the front shell and the neck and a color selection electrode, which as a result a plurality of perforations for the passage of the electron beam has an electron beam transmission ratio of has more than 40% and is arranged in the vicinity of the luminescent screen, characterized in that each of the perforations (15) has a part facing the fluorescent screen (5) and a part facing the electron beam gun (7) and the Axes (16; 17) of the two parts are offset from one another, -12- 40981 3/07 59 -12- 7264122 wherein the offset (D) in the center of the color selection electrode (6) is substantially equal to zero and to the edge region of the Color selection electrode increases. 2. color picture tube according to claim 1, characterized in that in the rjuid area of the color selection electrode (6) the axes (16) of the perforation parts facing the electron beam gun (7) are closer to the center of the color selection electrode than the axes (17) of the perforation parts facing the fluorescent screen (5). 3. Color picture tube according to claim 1, characterized in that the perforations each have a wall inclined towards the edge region of the color selection electrode (6), wherein the Inclination is defined by the following equation: T s (t - s) tan θ, in which T is the projection of the inclined wall the perforation on the surface of the color selection electrode (6), t is the thickness of the color selection electrode, s represents the thickness of the wall area of the color selection electrode which is not inclined and t the inclination angle of the electron beam (11) with respect to the color selection electrode (6) is. 4. color picture tube according to claim 1, characterized in that the perforations (15) are circular. 5. color picture tube according to claim 1, characterized in that the perforations are strip-shaped. 409813 / 0-759 6. Color picture tube according to claim 1, characterized in that the width of the perforation facing the luminescent screen (5) is smaller than the distance between the perforations. 409813/0759