DE1015842B - Electron beam tubes for displaying color television pictures - Google Patents

Description

GERMAN

The invention relates to a cathode ray tube for reproducing color television pictures.

Various cathode ray tubes are known which are used for displaying television images in Colors, especially natural colors, are capable of being used without filters or optical systems that combine two or more monochrome images into a single color image. The common property of these tubes is that they have one Have screen on which two or more luminescent substances, which in the event of electron impact in different Colors light up, attached in discrete, regularly arranged surfaces. By doing These areas are chosen to be very small and arranged in a regular pattern, which combines Eye the different color parts of the picture and form a color picture.

In the case of cathode ray tubes of the type described above, it is necessary to use the different colored areas to be stimulated on the screen independently of each other. There are various types of cathode ray tubes for this purpose has been proposed. On the one hand there are tubes in which an equal number of Electron beams are generated like there are basic colors in the screen, and on the other hand there are types in which only an electron beam is generated that passes through a control electrode near the screen directed at different colored surfaces at different moments. On this last one Tube type, the images are generated one after the other in the individual basic colors. The control electrode often consists of a grid that is a certain distance in front of the screen, i. H. on the cathode side, and is composed of two parts, between which the color selection voltages be created. Most often these two parts are connected by parallel wires into a single one Level formed, which are connected one by one to the other.

In the first-mentioned type of tube, a so-called mask electrode is arranged in front of the screen. This mask electrode contains a large number of openings, and the electron beams are below passed through these openings at different angles and hit them on the screen different luminescent surfaces. This mask can also consist of a large number of parallel wires.

With both types of tubes, the electron beams are deflected over the entire surface of the screen distracted.

It is known that there is a great advantage with these cathode ray tubes, in the space between the screen and the previous one

Cathode ray tube for reproduction
of color television images

Applicant:

Chromatic Television Laboratories Inc.,
New York, NY (V. St. A.)

Representative: Dr. rer. nat. P. Roßbach, patent attorney,
Hamburg 1, Mönckebergstr. 7th

Claimed priority:
V. St. v. America May 10, 1954

Craig S. Nunan, Berkeley, Calif. (V. St. Α.),
has been named as the inventor

Electrode to generate an electric field, whereby the electron beam is additionally focused. It in this case it is possible to determine the ratio of the surface area of the passage part to the perforated Electrode and its solid part to be dimensioned large, whereby the efficiency of the tube is greater than will be without focusing.

The simplest way to create the focus field is to make the screen conductive is made, e.g. B. by applying a thin metal layer and applying a voltage between the perforated electrode and the picture electrode, the picture electrode opposite the pierced electrode is positive.

A difficulty arises with this refocusing one that deals with the electron optical effect of the electric field between the screen and the preceding electrode related, which will be explained in more detail below.

It is known that an electric field between an electrode and an electrode arranged in front of it with openings always has a focusing effect on the electron beam passing through an opening the latter electrode enters the space between the electrodes when the perforated electrode has a lower potential than the other electrode. This is because electron lenses are formed between these electrodes. It has been found that the relationship between the focal lengths of these lenses and the distance between the electrodes practically only from that

7.09'697/119

Voltage difference between the two electrodes depends. You can see this difference in tension here z. B. choose such that the focal points of the electron lenses are on .the second electrode, in seen the direction of electron movement. Each electron bundle with almost exclusively parallel ones Electron trajectories that pass through the perforated electrode are therefore exactly on the second electrode focused. If this voltage difference is therefore at least two in discrete, regularly distributed Surface-mounted luminescent substances, which are produced by electron impact in different colors light up and two at a certain distance from each other in front of the screen and practically parallel contains mutually arranged grids, and is characterized in that the second, i. H. that continues from the grid remote from the cathode has a higher potential than the first that the space between the two

kept constant and is z. B. the distance io th grid and the screen is almost field-free and

enlarged between the electrodes, the focal points still remain on the second electrode lie.

However, the above only applies to electron beams that are perpendicular to the surface of the perforated electrode drop. If an electron beam falls obliquely on the perforated electrode, it passes through he between the. two electrodes a crooked one that the screen on the side of the electron syringe is concave and so curved that it practically coincides with the plane of the focal points of the electron lenses, which is formed by the two grids. In a cathode ray tube according to the invention is the function of the conductive screen, such as that in the known tubes described above is used, separated into two parts, as it were. The required electric field is generated by means of the second

Orbit, since the electrons naturally strive to

to follow the lines of force between these electrodes. 20 grating is formed and the light is emitted by means of a

So there is a difference in the dwell time of the screen, the germ higher potential than

Electrons between the two electrodes, if that needs to lead to the preceding electrode,

the electrons of a perpendicularly incident elec- The electric field between the first and the

tx-onenstrahls and if the electrons of an oblique second lattice naturally forms a curved one

incident electron beam the effect of the 25 focal plane. So it is possible in this way-

Focusing are subject. This occurs with cathode ray tubes! the one described above Kind in which the electron beam or beams are deflected over a large angle borrowed to create an image that is in focus virtually over the entire surface of the screen. There in the space between the second grid and the screen no longer changes the focus

will. In the middle of the screen the elec- 30 may fall, this space must be field-free. this

electron beams are practically perpendicular to the perforated electrode, and on the sides they close one relatively a large angle with it. The deflection angle for many tubes is 72 ° from one can be achieved in a simple manner in that the screen is made conductive and. electrically conductive with connected to the second grid. You can z. B. on the side of the picture facing the cathode

Edge to the other side of the picture and with modern screens a thin, electron-permeable,

Apply a reflective metal layer. However, it could also be a thin metal layer in a known manner be attached between the support of the screen and the luminescent substances. This metal layer must in this case of course for the light rays emitted by the luminescent substances be permeable. In certain cases it is even possible to do without the screen altogether to make it conductive, namely if he

Tubes even 90 °. This has the consequence that an electron beam which is exactly in the center of the image the screen is focused, over-focused at the edges of the screen. So the focus falls in front of the screen.

One might imagine that the bundles could always be kept in focus on the screen, if this screen had a certain curvature. However, this is impossible because, as said above, the

Ratio between the focal lengths of the electrons 45 has sufficiently high secondary emissions, lenses and the distance between the electrodes by taking the potential difference between the two

can be changed completely by the tension ratio of the through-grids: the location of the burning holes Electrode and the screen is conditioned. changed point level compared to the second grid One can be the consequences of the above. It is Z. B. possible, this focal plane wrong illustration, d. H. the creation of an image. 50 to choose so that it goes through the edges of the grid which only goes through the grille sharply in the middle and very much on the sides. In the middle lies the plane is out of focus, reduce to a minimum by, seen from the cathode, in a Geden Electrodes such a voltage is applied. know distance behind the bars. This is essential that a sharp focus at a point between as in this case a simple structural solution to the center of the screen and the edges occurs. The second grille can be attached. It can with the blurring in the middle and at the edges is approximating to the edges of the screen same, but less than the fuzziness to be consolidated.

the edges of a screen in which the center of the The concave shape of the screen is natural

Image is sharp, is of great importance when the screen is immediately

It is clear that with large sized screens, the 60 bar is attached to the picture window. This Fenalso require large angles of deflection, this solution has a shape that resembles the atmospheric one

is not yet entirely satisfactory. The invention now provides means by which the focusing of the Electron beams over the entire surface of the image is greatly enhanced.

A cathode ray tube for displaying color television pictures according to the invention consists of a vented flask, part of which serves as a window for observing the image and the min

At least one electron syringe and a screen 7 ° can be applied.

Pressure can resist well.

It is possible to use the first grid as a mask electrode in the construction according to the invention or use this to carry out the color selection. In the latter case, the first grid is made up of parallel lines Wires joined together, one around the other, to form two Groups between which the color selection voltage

A very important advantage achieved according to the invention is that the deflection of the electron beam as a result of the color selection voltages over the entire surface of the screen is the same if the requirement of an even focus on the screen is met. It results namely, both from calculations and from experiments that the change in focal lengths over the surface of the screen and the change in color deflection sensitivity follow the same course exhibit.

If parallel wires are used in the first grid, it does not matter whether the first grid is a If a mask electrode or a color selection electrode is, the various luminescent substances are known placed on the screen in strips parallel to the wires of the first grid. It will be there naturally ensured that the centers of the openings between the wires of the first grid and the Color strips coincide exactly.

The second grid preferably consists of parallel ones Wires, and if the first grid is also composed of parallel wires, then the The direction of the wires of the second grid is preferably perpendicular to the direction of the wires of the first grid chosen for the following reason. The openings between the wires in the first grid form cylindrical lenses so that the focal point on the screen is linear. The openings between the wires of the second grid form slightly diverging, cylindrical electron lenses, whereby these focal lines are stretched out approximately in the longitudinal direction. However, this does not have a disruptive effect, since the The length of the focal line is already very small and because the stripes of color are perpendicular to the direction of the wires of the second grid and there is no danger that the electrons will have other colored stripes on the Screen will hit.

When the invention applies to cathode ray tubes with parallel wires in the first grid and with phosphor strips Performed on the screen, it is possible to get the optimal even focus and color deflection sensitivity come close by using a screen that is only in a single screen Direction is curved, d. H. forms part of a straight cylindrical surface, the axis of which is to the direction of the wires of the first grid is perpendicular. When using this cylindrical shape of the screen With a deflection angle of 72 °, the color deflection sensitivity and the size of the focal points can exceed the screen is constant up to about 2.2% of the opening width being held. In practice this means e.g. B. that the focal point on the screen between May vary between 0.0075 cm and 0.0088 mm. For a tube with a flat screen and a flat one Lattice and otherwise with a very similar design, this change would be about 11% instead of 2.2. For a tube with a deflection angle of 90 ° and with two gratings, the focal point can e.g. B. between 0.0075 and. 0.01 cm must be kept constant. The color deflection sensitivity is then constant up to 3%. If only a single grating were used in this case, the change in color deflection sensitivity would occur about 20% and the change in focus size is more than 100%, d. H. from a medium of 0.0075 to a medium of 0.0175.

The invention is explained in more detail below with reference to a drawing. In this drawing, as For example, assume a cathode ray tube in which the first grid consists exclusively of parallel wires contains, the one connected to the other, the second grid exclusively parallel Contains wires, the direction of which is perpendicular to the wires of the first grid, the screen immediately attached to the window and on the cathode side with a thin, conductive, reflective Metal layer is coated. The tube is also provided with three luminescent substances on the screen, which emit light in three basic colors through electron impact, d. H. Red, green and blue that are chosen so that together they give the impression of a white image with the same excitation.

In the drawing is

1 shows a schematic representation of a cathode ray tube of the type described above;

Fig. 2 shows a picture of part of a section through the screen of a tube according to Fig. 1;

Fig. 3 is an image of a portion of a bi-directional curved screen and an associated one Lattice set;

Fig. 4 is a picture of a cylindrical screen with the associated grids, and

Fig. 5 is a graph showing a number of curves for a tube according to the invention indicate the relationship between the spacing of the two grids and the curvature of the screen.

According to Fig. 1, the cathode ray tube consists of a piston, which consists of a glass neck 1, a metal cone 11 and a glass window 13 which is curved outward. The electron syringe is located in the neck 1, that of the cathode 3, a control electrode 5, a first anode 7 and a second Anode 9 is assembled, the latter being connected to a metal cone 11. Located in front of the window 13 the grid 17 with wires parallel to the plane of the drawing. Between this grid 17 and the Tube neck is a grid that contains. Exclusively wires perpendicular to the plane of the drawing one to the other are connected to one another so that two grids 19 and 20 are formed as it were. These grids 19 and 20 each have a lead wire 21 and 22, respectively, which are connected to the source of the color selection voltages are connected.

The assembly of the screen can be seen more clearly from FIG. 2, which shows a small section shows enlarged from the view of FIG. 2, so that the screen curvature can no longer be seen. on The phosphor strips are located in the window 13, the strips 24 being red as a result of electron impact Light, the strips 26 emit green light and the strips 28 emit blue light. On this strip lies a thin, reflective metal layer on the cathode side 15th

The operation of the tube shown in Figs. 1 and 2 is briefly as follows.

The electron syringe forms an electron beam, which by means of a 'deflection system, not shown, which is located approximately at the point of separation between the cone and the neck 1, in two Directions is deflected so that the entire screen is scanned. Before the electron beam reaches the screen, it goes through the assembly of the grids 19, 20 and 17. When between the Grid 17 and the grids 19 and 20 a certain voltage difference is applied, the beam focused on the screen. Under the tension of the grids 19 and 20, the mean tension is here the area of these grids, because over the access

guide wires 21 and 22 is an alternating voltage between the. Grids 19 and 20 created, whereby the Electron beam is directed onto one of the rows of strips 24, 26 or 28.

The spacing between the wires of the grid 17 is not critical, but is preferably of the same size like the distance between the center of two consecutive green phosphor strips, since there is then is possible to make the shadow of the grid 17 practically invisible on the screen. The wires the grids 19 and 20 are arranged such that the centers of the openings between two adjacent Wires are electron-optically opposite the centers of the green phosphor strips 25, d. i.e., the wires are arranged such that when an electron beam passes through the center of an opening between two Wires goes and if there is no potential difference between the wires, the middle of the this opening belonging to the green phosphor strip is hit.

The potential of the grids 19 and 20 is preferably selected to be 200 to 400 V lower than the potential of the cone 11, which itself has a voltage of 5000 to 8000 V with respect to the cathode. Between a color selection voltage of approximately 400 V is applied from tip to tip to the grids 19 and 20. That Grid 17 has a potential which is significantly higher than the mean potential of the surface of grids 19 and 20 is, and is chosen such that the electron beam is focused at any point on the screen is. The distance between the grid 17 and the surface of the grids 19 and 20 is preferably about ten to fifteen times the distance between the wires of the grids 19 and 20 is chosen.

To explain the invention follows below a short mathematical explanation of the curvature condition of the screen.

As noted above, the spacing between the two grids is not essential.

A suitable value is selected for this, which is denoted by D. With a certain tension between the grids, a focal plane arises and the condition for precise focusing is that the curvature of the screen should be exactly the same as the curvature of this focal plane. If the distance of any point on the screen from the second grid is denoted by F , it follows that the condition of precise focusing is given by the equation:

~ D

ί + K sec ² Θ

day ² /?

1 +

K see ² Θ ] / l + K sec ² Θ

j / l

can be represented. Since the distance D, as stated above, can be selected as desired, only the ratio F [D is important. In the previous equation, Θ is the angle of incidence of the electron beam at any point on the first grid, ie the angle with the normal at this point; β denotes the angle of the normal at the point of impact on the first grid with the projection of the beam onto the surface perpendicular to the direction of the wires of the first grid, K denotes the minimally

value of the quotient

in which the electron beam is focused on this screen at the edges of the screen, where V _{1 is} the voltage difference between the first grid and the cathode and V _{2 is} the voltage difference between the second and first grid.

Fig. 3 shows how the screen 13 is curved in two mutually perpendicular directions in such a way that the above equation is satisfied. As can be seen from the figure, F is zero at the corner points of the screen. This results in a simple, structural solution for fastening the grille 17 and also a minimum thickness of the structure of the screen 13 and the grille 17.

5 shows a number of curves, the values of the quotient F] D as a function of tga for various values of tg /? and the voltage ratio K are plotted. Curves 25, 27, 29 relate to a tube with a deflection angle of 90 ° and curves 31, 33 and 35 to a tube with a deflection angle of 72 °, ie that for the first set of curves the maximum value of the angle Θ Is 45 ° and for the second set of curves is 36 °.

Fig. 5 is a graph with the abscissa tga, ie the tangency of the angle of the normal at the point of impact of the electron beam on the first grid and the projection of the beam on the plane through the point of impact perpendicular to the first grid and parallel to the direction of the wires of the first Grid and the ratio F / D are plotted as the ordinate of the graph.

The series of curves 25, 27 and 29 are calculated for a value of A '= 1.829 and the series of curves 31, 33 and 35 for a value of K = 2.210. In curve 25, the parameter tg /? = 0, in curve 27 tgy # = 0.40, in curve 29 tg _/ δ = 0.60, in curve 31 tgß = 0, in curve 33 is tg / S = 0.308 and for curve 35 is tg /? = 0.346. The curves 29 and 35 relate to the edges of the screen.

The curve 30 denotes the change in the ratio F / D as a function of tg /?, Where tga = 0 is selected as the parameter for a tube with a deflection angle of 90 °, where the curvature is greatest. As can be seen from the curves in FIG. 5, the curvature of the screen with respect to an axis parallel to the wires of the first grid is significantly less than with respect to the axis perpendicular thereto. From the practical coincidence of curves 25, 27 and 29 at the edge of the screen, ie at tga = 0.8, it follows that the focal plane has practically no curvature in this part.

The maximum curvature of the plane through the tube axis and parallel to the wires of the second grating for accurate focusing is only about one third of that in the horizontal plane. Many advantages of the invention can thus already be achieved if a screen is used which forms part of a straight cylindrical surface. In the case of a 90 ° deflection tube, the curvature of such a cylinder satisfies the values determined by curve 27, and for a tube with a deflection angle of 72 ° that of curve 33. These curves apply to values of the angle β at which the defocus on the upper and lower side of the screen and on the axis is about the same. The electron beam is slightly below the center of the screen.

■■ ■■ i

focused and slightly over-focused at the top and bottom. For a tube with a deflection angle of 90 °, tgß 0.40 is found, and for a tube with a deflection angle of 72 °, tg /? 0.308. Such a design is shown in FIG.

The use of a cylindrical screen has the advantage that it can be more easily made precisely can be used as a screen that is curved in two directions.

For a better understanding of the various angular values and other factors in the above description, a small portion of a tube according to the invention is shown in FIG. 6 on an enlarged scale. In this figure, the area of the first grid is indicated by 40 and contains the grid wires 41. The area of the second grid with the grid wires 43 is indicated by 42. The luminescent screen is labeled 44. It contains the luminescent strips 45 for the different colors. A deflected electron beam is indicated by 46. It intersects surfaces 40, 42 and 44 at points 47, 48 and 49, respectively. Through point 47 , two surfaces 50 and 51 are erected perpendicularly on surface 40. These · surfaces 50 and 51 are; perpendicular to each other. A surface 52 is erected parallel to the surface 40 at an arbitrary point of the line of intersection of the two surfaces 50, 51. The straight line 47-53 forms the normal to the surface 40 at the point of intersection 47 of the electron beam 46 with the surface 40. The line 47-54 gives the projection of the electron beam onto the surface 51 and the line 47-55 the projection onto the surface 50 If the point of intersection of the electron beam 46 with the surface 52 is given by 56, then the lines 47-56 and 47-53 close the angle Θ, the lines 47-53 and 47-55 the angle β and the lines 47-53 and 47 -54 the angle α.

Claims (8)

Patent claims: 1. Cathode ray tube for the reproduction of color television pictures emerging from a vented flask of which a part serves as a window for observing the image and which at least an electron syringe and a screen F. D. see ² θ 1 + with at least two luminescent substances applied in discrete, regularly distributed surfaces, which light up in different colors due to electron impact, and two in a certain Distance from each other in front of the screen and grids arranged practically parallel to each other contains, characterized in that the second, d. i.e., the grid further from the cathode a higher potential than the first grid that the space between the second grid and the The screen is almost field-free and the screen is concave and on the side of the electron syringe is so curved that it practically coincides with the plane of the focal points of the electron lenses covers formed by the two grids. 2. Cathode ray tube according to claim 1, characterized in that the screen is on the window. 3. Cathode ray tube according to claim 1 or 2, characterized in that the screen is on the cathode side is coated with a thin, electron-permeable, reflective metal layer is, which is electrically conductively connected to the second grid. 4. Cathode ray tube according to claim 1, 2 or 3, characterized in that the first Grid consists of parallel wires which are connected to one another one around the other so that two groups arise between which control voltages can be applied. 5. Cathode ray tube according to claim 4, characterized in that the second grid consists of parallel wires, the direction of which is perpendicular to the direction of the wires of the first grid is. 6. cathode ray tube according to claim 4 or 5, characterized in that the screen has a Forms part of the surface of a straight cylinder, the axis of which is parallel to the direction of the wires of the second grid runs. 7. cathode ray tube according to claim 5 or 6, characterized in that the curvature of the Screen is such that over a large part of its surface the equation: 1 + tg »0 | / T + i £ sec ² 0 'sec ² Θ 1 + X see ² © is fulfilled. 8. cathode ray tube according to claim 1, 2, 3, 4, 5, 6 or 7, characterized in that at least part of the edges of the second grid are zero-distance from the screen. For this purpose 2 sheets of drawings © 709 697/119 p.