EP0138264A2 - Colour display tube - Google Patents

Abstract

A color image display tube with an electron beam generating system (6) of the "in-line" type in an evacuated piston (1) for generating three electron beams with their axes in one plane (6, 7, 8). The axis of the middle beam (7) coincides with the tube axis (9). The electron beams converge on a screen (10) attached to a wall of the piston and are deflected via this screen in two mutually perpendicular directions by means of a first and a second deflection field (80, 91), the direction of the first deflection field being parallel to the plane mentioned runs. At its end, the electron beam generating system is provided with curved field formers (27, 28), which, as far as possible, cover the grids described by the electron beams on the screen. Each field former contains at least two plates (29, 30, 31, 32) made of ferromagnetic material which are essentially in extension from one another and are separated from one another by gaps (34, 35), which plates are symmetrical with respect to the plane mentioned and the central tube axis, and the curved field formers with their hollow sides face the three beams, so that the field formers design the first deflection field in the form of a pillow at the location of the electron beams. At least the plates (29, 32) which are furthest from the plane mentioned are provided at their end facing away from the plane mentioned with flat bends (33) which extend in the direction of the central electron beam. In such a color picture display tube, the losses in the second deflection field are low and this field is almost not distorted. The desired pillow-shaped distortion of the first deflection field in the field formers is further increased.

Description

The invention relates to a color picture display tube with an "in-line" type electron gun in an evacuated piston for generating three electron beams with their axes in one plane, the axis of the central beam coinciding with the tube axis, which electron beams on a screen, which is mounted on a wall of the piston, converge and are deflected via this screen in two mutually perpendicular directions by means of a first and a second deflection field, the direction of the first deflection field being parallel to the plane of the electron beam axes, which electron gun system is bent at its end Field formers are provided which allow the raster described by the electron beams on the screen to coincide as far as possible, and each field former has at least two plates a us contains ferromagnetic material, which lie symmetrically with respect to the plane mentioned and to the central tube axis, and the curved field formers with their hollow sides face the three beams, which field formers make the first deflection field in the form of a pillow in the place of the electron beams.

A common problem with color display tubes with an "in-line" type electron gun is the so-called image coma. This coma is expressed in the fact that the dimensions of the grids, which describe the two outer electron beams on the screen, differ from those of the central beam. This is caused by the eccentric position of the outer electron beams in relation to the field for the vertical deflection. In U.S. Patent No. 4,196,370 a large number of patents mentioned in which partial solutions are specified. These solutions consist of the use of a magnetic field of conductive and / or shielding rings and plates which are mounted at the end of the beam generating system and which reinforce or weaken the deflection field or the deflection fields in places along part of the path of the electron beams. With some of these means it is possible to essentially coincide the raster described by the three electron beams on the screen. A disadvantage of using such means, however, is that defocusing occurs in the outer rays during the deflection, which is expressed in a deformed impact spot on the screen, which is surrounded by a fog. One of these patents is US Pat. No. 3,594,600, which describes a color display tube in which the grids described by the three electron beams coincide by arranging two elongated, C-shaped magnetic screens outside the outer electron beams. This shields the outer electron beams from the edge field of the horizontal deflection field (the vertical field lines), while this edge field is allowed for the middle electron beam. The three electron beams are shielded from the edge field of the vertical deflection field (the horizontal field lines), which edge field is completely guided around the three beams. These field formers therefore only influence the horizontal coma and not the vertical coma.

In the published Dutch patent application 7801317 a deflection coil system is described in which field-forming means are attached to the deflection coil system. They consist, for example, of two soft magnetic elements which are attached to one another diametrically opposite one another outside the horizontal deflection coil and essentially transversely to the magnetic field of the vertical deflection coil on the neck side of the deflection coil system. A disadvantage of using such field-shaping means is that a large part of the vertical deflection field is from these means is directed around the beams, thereby reducing the sensitivity to deflection of the tube / coil system.

A color image display tube of the type mentioned in the opening paragraph is described in the as yet unpublished Dutch patent application 8204465 (PHN 10499), which can be considered to be incorporated herein and which is believed to be state of the art. The field formers described in this patent application design the first deflection field (the vertical deflection field) in a pillow shape. This pillow-shaped field essentially contains a two-pole field with a six-pole component. As a result of this pillow shape, the field has the appropriate strength and shape at the location of the electron beams lying outside the electron beam axes, as a result of which the deflection defocusing of the external beams is greatly reduced. Since, in contrast to the field formers in the deflection coil system according to the Dutch patent application 7801317, these field formers are relatively close to the electron beams, only a relatively small part of the deflection field is deformed, which means that only a little additional deflection energy is required. In the mentioned Dutch patent application 8204465 it is further described that it is advantageous to make slots in the field formers and to produce these field formers from two or three plates lying in an extension from one another. The task is to reduce the losses in the horizontal deflection field (the second deflection field).

Measures to reduce losses in the second deflection field are taken in Dutch patent application 8301712 (PHN 10674), which has also not yet been published and which can be regarded as incorporated herein. The field formers according to this patent application each consist of at least two plates lying in extension, which, as described above in the first paragraph, lie with respect to the plane mentioned by the beam axes and the tube axis. The gaps between the plates are on the side facing away from the electron beams at a distance from these plates from other plates overlaps so that magnetic shunts are created for the second deflection field in each field former.

The invention has for its object to provide a color display tube, in which the losses in the second deflection field are further reduced by the field shapers, the second deflection field is almost not deformed and the desired cushion distortion of the first deflection field in the field shapers is further increased.

This object is achieved according to the invention in a color image display tube of the type mentioned in the introduction in that in each field former at least the plates which are furthest away from the plane mentioned are provided with angled, essentially flat plates at their end facing the plane mentioned extend towards the central electron beam.

The invention is based on the knowledge that by attaching the angled plates which extend to the central electron beam, the first deflection field (the vertical field) is guided further to the central beam, as a result of which this field becomes pillow-shaped. A part of the second deflection field (the horizontal field), which is otherwise guided around the beams via the tangentially arranged plates (the plates lying essentially in an extension of one another) around the beams, is also further guided to the beams by these radially directed plates this field is enhanced at the location of the electron beams with respect to the state without the radially directed plates (Dutch patent applications 8204465 and 8301712). An advantage of the larger pillow shape of the first deflection field in some cases is that the desired coma correction is increased, as a result of which the length of the field shapers in the direction of propagation of the central electron beam can be shorter than the length of the field shapers according to the mentioned Dutch patent applications 8204465 and 8301812. This shorter length of the field formers means that less energy loss occurs in the second deflection field. Also the tangential parts the field former form shorter arcs compared to the field former according to the Dutch patent application 8204465, whereby less loss occurs in the second deflection field (the horizontal field).

Measurements on image display tubes according to the invention have shown that there is almost no loss in the horizontal field compared to the tubes with field shapers according to Dutch patent applications 8204465 and 8301712. In addition, it is shown that the horizontal coma, the horizontal and the vertical astigmatism and the anisotropic astigmatism differ only slightly from those when using the previously used coma correction means, so that the deflection coils need only be adjusted slightly or not at all when the field shapers according to the invention are introduced .

Using field formers with radially extending parts in deflection coils (Dutch patent application 7801317) is difficult. The effective guiding of the deflection fields to the electron beams is only possible in the electron beam generation system and only in the manner according to the invention.

A preferred first embodiment of the field former for an image display tube according to the invention is characterized in that each field former is four in extension from one another and symmetrical with respect to the. contains the above-mentioned flat plates separated by three columns.

By attaching one or more gaps, the attenuation of the second deflection field at the location of the rays is reduced; with a correct dimensioning of the gaps it can be achieved that the field at the location of the electron beams is almost homogeneous.

A second preferred embodiment of the field formers for a tube according to the invention is characterized in that the gap intersecting the plane is wider than the column lying above and below the plane. The widening of the gap intersecting the plane ensures that the second deflection field on the Point of the rays becomes more homogeneous.

A third preferred embodiment of the field formers for a tube according to the invention is characterized in that, in addition, the plates which are closest to the plane mentioned are provided at their end facing away from the plane with angled flat plates which point in the direction of the central electron beam extend. By attaching these additional plates, the shape of the first deflection field is made pillow-shaped at the location of the electron beams.

A fourth preferred embodiment of the field formers for an image display tube according to the invention is characterized in that the electron beam generating system is equipped at its end with a centering cup, the plates lying in extension from one another being fastened to the inner wall or outer wall of this centering cup. In this way it is possible to easily attach the field formers to the electron gun. If the plates, which are essentially in an extension of one another, are fastened to the outer wall of the centering cup, the centering cup must be provided with slots through which the angled plates extend in the direction of the central electron beam. By placing the plates partially inside and outside the centering cup, the influence of the gaps on the second deflection field (the horizontal field) can be changed.

A fifth preferred embodiment of the field formers for a picture tube according to the invention is characterized in that at least one of the gaps between the plates is overlapped in a known manner on the side facing away from the electron beams at a distance from the plates of shunt plates. The shunt plates provide a magnetic resistance in the field formers, whereby the field is less distorted.

• Fig. 1 einen Längsschnitt durch eine Farbbildwiedergaberöhre nach der Erfindung,
• Fig. 2 eine teilweise aufgebrochene Ansicht eines Elektronenstrahlerzeugungssystems, wie es in der Röhre nach Fig. 1 verwendet wird,
• Fig. 3 einen Schnitt durch die Fig. 2 längs der Ebene III-III,
• Fig. 4a, b, c und d schematisch eine Lösung nach dem Stand der Technik und die Auswirkung auf den Strahl und den Auftreffleck sowie auf das gewünschte Feld,
• Fig. 5a einen Teil des Vertikalfelds mit Feldformern nach einer älteren Patentanmeldung,
• Fig. 5b den Verlauf dieses Vertikalfelds, geteilt durch das von den Ablenkspulen zugeführte Vertikalfeld, abhängig von der Stelle x auf einer Achse senkrecht zu den Strahlachsen,
• Fig. 5c einen Teil des Horizontalfelds mit Feldformern nach der älteren Patentanmeldung,
• Fig. 5d den Verlauf dieses Horizontalfelds, geteilt durch das von den Ablenkspulen zugeführte Horizontalfeld, abhängig von der Stelle x auf einer Achse senkrecht zu den Strahlachsen,
• Fig. 6a eine Abbildung analog der Fig. 5a, aber jetzt mit überlappten Spalten in den Feldformern nach einer anderen älteren Patentanmeldung,
• Fig. 6b eine graphische Darstellung analog der Fig. 5b für die Feldformer und das Feld gemäss Fig. 6a,
• Fig. 6c eine Abbildung analog der Fig. 5c, aber jetzt mit überlappten Spalten in den Feldformern gemäss der anderen älteren Patentanmeldung.
• Fig. 6d eine graphische Darstellung analog der Fig. 5d für die Feldformer und das Feld gemäss Fig. 6c,
• Fig. 7a eine Abbildung analog den Fig. 5a und 6a, aber jetzt mit Feldformern für eine erfindungsgemässe Bildwiedergaberöhre,
• Fig. 7b eine graphische Darstellung analog den Fig. 5b und 6b für die Feldformer und das Feld gemäss Fig. 7a,
• Fig. 7c eine Abbildung analog den Fig. 5c und 6c, aber jetzt mit Feldformern für eine erfindungsgemässe Bildwiedergaberöhre,
• Fig. 7d eine graphische Darstellung analog Fig. 5d und 6d für Feldformer und das Feld nach Fig. 7c,
• Fig. 8 eine andere Ausführungsform der Feldformer für eine erfindungsgemässe Bildwiedergaberöhre in einem der Fig. 3 analogen Querschnitt,
• Fig. 9 eine weitere Ausführungsform der Feldformer für eine erfindungsgemässe Bildwiedergaberöhre in einem der Fig. 3 analogen Querschnitt,
• Fig. 10a eine Abbildung analog der Fig. 7a mit Feldformern für eine erfindungsgemässe Bildwiedergaberöhre,
• Fig. 10b eine graphische Darstellung analog der Fig. 7a für die Feldformer nach Fig. 10a,
• Fig. 10c eine Abbildung analog der Fig. 7c mit Feldformern für eine erfindungsgemässe Bildwiedergaberöhre, und Fig. 10d eine graphische Darstellung analog der Fig. 7d für Feldformer und das Feld nach Fig. 10c.

Embodiments of the invention are explained below with reference to the drawing. Show it

• Fig. 1 shows a longitudinal section through a color image display tube according to the invention,
• FIG. 2 is a partially broken away view of an electron gun as used in the tube of FIG. 1.
• 3 shows a section through FIG. 2 along the plane III-III,
• 4a, b, c and d schematically a solution according to the prior art and the effect on the beam and the impact leak and on the desired field,
• 5a shows a part of the vertical field with field formers according to an older patent application,
• 5b shows the course of this vertical field, divided by the vertical field supplied by the deflection coils, depending on the position x on an axis perpendicular to the beam axes,
• 5c shows a part of the horizontal field with field formers according to the earlier patent application,
• 5d shows the course of this horizontal field, divided by the horizontal field supplied by the deflection coils, depending on the position x on an axis perpendicular to the beam axes,
• 6a is an illustration analogous to FIG. 5a, but now with overlapping columns in the field formers according to another older patent application,
• 6b is a graphical representation analogous to FIG. 5b for the field former and the field according to FIG. 6a,
• 6c is an illustration analogous to FIG. 5c, but now with overlapping columns in the field formers according to the other older patent application.
• 6d is a graphical representation analogous to FIG. 5d for the field former and the field according to FIG. 6c,
• 7a is an illustration analogous to FIGS. 5a and 6a, but now with field formers for an image display tube according to the invention,
• 7b is a graphical representation analogous to FIGS. 5b and 6b for the field former and the field according to FIG. 7a,
• 7c is an illustration analogous to FIGS. 5c and 6c, but now with field shapers for an image display tube according to the invention,
• 7d is a graphical representation analogous to FIGS. 5d and 6d for field formers and the field according to FIG. 7c,
• 8 shows another embodiment of the field former for an image display tube according to the invention in a cross section analogous to FIG. 3,
• 9 shows a further embodiment of the field formers for an image display tube according to the invention in a cross section analogous to FIG. 3,
• 10a is an illustration analogous to FIG. 7a with field formers for an image display tube according to the invention,
• 10b is a graphical representation analogous to FIG. 7a for the field former according to FIG. 10a,
• 10c is an illustration analogous to FIG. 7c with field shapers for an image display tube according to the invention, and FIG. 10d is a graphical illustration analogous to FIG. 7d for field shapers and the field according to FIG. 10c.

In Fig. 1, a color image display tube of the "in-line" type is shown in longitudinal section. In a glass bulb 1, which is composed of an image window 2, a cone 3 and a neck 4, an electron beam generation system 5 is accommodated in this neck, which generates three electron beams 6, 7 and 8 lying with their axes in one plane (the drawing plane) . The axis of the central electron beam 7 coincides with the tube axis 9 before the deflection. The image window 2 is provided on the inside with a large number of triples made of phosphor lines. Each triple contains a line of blue fluorescent, a line of green fluorescent, and a line of red fluorescent. All triples together form the screen 10. The fluorescent lines run perpendicular to the plane of the drawing. A perforated mask 11 is arranged in front of the screen, in which a plurality of elongated openings 12 are provided, through which the electron beams 6, 7 and 8 pass, each of which strikes only fluorescent lines of a single color. The three electron beams 6, 7, 8 lying in one plane are deflected by a deflection coil system 13. Through the application of the invention, a vertical coma correction is carried out on the beams without any distortion of the impingement leak of the outer electron beams and with almost no loss of deflection energy of the horizontal field, as will be explained in more detail below with reference to the figures.

FIG. 2 shows a broken away view of the electron gun 5. It consists of three separate electron guns 14, 15 and 16. However, it is also possible to apply the invention to a so-called integrated electron gun, as described for example in US Pat. No. 4,196,370, in which the electron gun has a number of electrodes have in common. The beam generators 14, 15 and 16 each contain a control electrode 17 with an opening 18. Opposite this opening, a cathode (not visible here) is installed in this control electrode for generating the electron beams. Each beam generator also contains a second grating 19, a third grating 20 and a fourth grating 21. The grids 17, 19 and 20 are fastened to glass rods 23 by means of metal strips 22. The grids 21 are attached to the bottom of a common centering cup 24 made of non-ferromagnetic material. The bottom 25 of the centering cup 24 broken open here is provided with three openings 26 through which the electron beams pass. Attached to the inner wall of the centering cup 24 are two curved field formers 27 and 28, each consisting of four curved plates 29, 30, 31 and 32, the plates 29 and 32 being provided with bends 33 extending towards the central electron beam. The bends 33 can be attached to the plates 29 and 32 or form a whole with them. The bends 33 can also be slightly curved or angled in themselves. All plates are made of ferromagnetic material with a thickness of 0.25 mm (eg an alloy with 58% by weight nickel and 42% by weight iron). The plates have a length of about 10 mm in the direction of propagation of the electron beams measured. Between the plates 29 and 30 and the plates 31 and 32 there are 0.5 mm wide gaps 34. There are 1 mm wide gaps between the plates 30 and 31. The diameter of the centering cup 24 is approximately 22 mm. The width of the plates 30 and 31 is 2.8 mm in the flat state. The width of the plates 29 and 32 is 3.7 mm in the flat state and the width of the bends 33 is 3.7 mm. If a magnetized multipole ring is used in the image display tube for the static convergence of the electron beams, as described, for example, in US Pat. No. 4,220,897 (PHN 8845), it is preferably attached to the bottom 25 of the centering cup 24. The field formers are preferably attached at least 22 mm from this ring in connection with the magnetization of the multipole ring.

FIG. 3, in which the same reference numerals are used as in FIG. 2, shows a cross section through the centering cup 24 in FIG. 2. By a suitable choice of the length of the plates 29 to 33, measured in the tube axis direction, and the angle d: the desired pillow-shaped field formation of the vertical field (the first deflection field) parallel to the line 36 and possibly also the horizontal deflection field (the second deflection field), the vertical to be influenced. The field formers 27 and 28 lie symmetrically with respect to the plane 36 through the beam axes (the plane of the drawing according to FIG. 1) and symmetrically with respect to the tube axis 9, which coincides with the axis of the central electron beam 7 before the deflection. As will be explained in more detail with reference to FIG. 8, a part of the plates can also lie outside the centering cup. It is also possible not to use a centering cup and to fasten the field formers together, for example with glass beads.

As shown schematically in FIG. 4a, the magnetic field, of which some field lines 40 are indicated, is attracted by the known rings 41 around the outer electron beams 42 and 43. The resulting field strength curve B in the plane through the bundle axes x (44, 45, 46) is shown in Fig. 4b with a solid line. The desired coma-free field is indicated by a dashed line. By using the rings 41, the magnetic field B at the location of the beam axes 44, 45 and 46 is equal to the desired magnetic field and the three grids described on the screen are made to coincide. The field does not have the correct field strength profile for the rays of the outer rays 42 and 43 which do not coincide with the ray axes, as a result of which a four-pole lens effect (four-pole field lines 47) shown in FIG. The radial arrows in Fig. 4c indicate the forces that affect the rays. The impact spots on the screen shown in FIG. 4d become elliptical and are surrounded by a fog. The axes of the ellipses in FIG. 4d form an angle of 45 ° with line 37. The elliptical shape of the impact spot is the result of underfocusing. The dashed fog areas 48 are the result of overfocusing.

5a, b, c and d illustrate the field shapers as described in the previously mentioned, not yet published Dutch patent application 8204465 (PHN 10499). 5a shows a part of the vertical field (the first deflection field), of which some field lines 50 are shown. In this field, two field formers 51 and 52, each consisting of one piece, are arranged at the end of the beam generator and distort the vertical field in the manner of a pillow in the desired manner. This pillow-shaped field essentially consists of a two-pole field with a six-pole component. 5b shows the course of the magnetic field B, the vertical x field, divided by the vertical field B _b supplied by the deflection coils, depending on the position x on the axis 53. The mutual distance between the axes of the electron beams 54, 55 and 56 is approximately 6.3 mm at the location of the field formers. With such a field course, the desired field after the dashed line 4b, it is possible to eliminate the four-pole error at the location of the side beams 54 and 56 and thus greatly reduce the deflection defocusing of these beams. FIG. 5c shows part of the horizontal field (the second deflection field), of which some field lines 57 are shown. 5d shows the course of the magnetic field B, the horizontal field, divided by the horizontal field B ₁ supplied by the deflection coils, depending on the position x on the axis 53. It can be seen from FIGS. 5c and d that the horizontal field at the location of the field former is greatly weakened by this type of field former, in particular in the case of the outside beams 54 and 56. This means that horizontal coma will occur.

6a, b, c and d illustrate the effect of field formers, as described in the previously mentioned, not yet published Dutch patent application 8301712 (PHN 10674).

FIG. 6a shows a part of the vertical field, analogous to FIG. 5a, of which some field lines 60 are shown. In this field, two curved field formers 61 and 62 are again arranged, each consisting of two curved plates 63, 64 and 65, 66 lying in the extension from each other and two curved plates 69 and 70 overlapping the gaps 67 and 68. However, plates 69 and 79 can also be flat. It can be seen from FIG. 6b, which is analogous to FIG. 5b, that the vertical field profile has not changed much by arranging the plates 69 and 70 with respect to the vertical field profile according to FIG. 6a.

FIG. 6c shows a part of the horizontal field, of which some field lines 71 are shown. It can be seen from FIG. 6d, which is analogous to FIG. 5d, that although the horizontal field is weakened by the arrangement of the columns 67 and 68, but also that the course in the x direction is relatively flat; in other words, the horizontal field is less distorted compared to FIG. 5d. This can also be seen from the comparison of FIGS. 5c and 6c.

7a, b, c and d explain the effect of the field formers for a color image display tube according to the invention as shown in FIG. 2. 7a shows, analogous to FIGS. 5a and 6a, part of the vertical field, of which some field lines 80 are shown. Two curved field formers 81 and 82 are arranged in this field in the manner shown in FIG. 2. Each field former consists of four curved plates 83, 84, 85 and 86 lying in the extension from one another, which are separated from one another by columns 87, 88 and 89. 55 bends 90 extend from the ends of plates 83 and 86 toward the central electron beam.

It can be seen from FIG. 7b, which is analogous to FIGS. 5b and 6b, that the field shape is substantially more pillow-shaped due to the bends 90. To obtain the required field quantity, the field formers 81 and 82 can therefore be shorter, measured in the direction of propagation of the central electron beam. By shortening the field formers, there is even less loss in the horizontal field.

FIG. 7c shows a part of the horizontal field, of which some field lines 91 are shown. It can be seen from FIG. 7d analogous to FIG. 6d that the horizontal field is weakened less by the bends 90 than in the state according to FIGS. 6c and d, while the course in the x direction is also flatter than in FIG. 6d. This can also be seen from the comparison of FIGS. 6c and 7c.

FIG. 8 shows another embodiment of the field shaper for an image display tube according to the invention in a cross section analogous to FIG. 3. For the sake of clarity, the reference numerals in this figure are the same as in FIG. 3. The plates 30 and 31 of the plates 29, 30, 31 and 32, which are essentially in an extension of one another, are arranged on the outside of the centering cup 24. The shape of the horizontal field (the second deflection field) can be influenced by this different position of the plates and the gaps 34. The Plates 29, 30, 31 and 32, which together form the curved field formers 28 and 29, can also be flat. If the plates 29 and 32 are also arranged on the outside of the centering cup 24, slots must be provided in the centering cup 24 through which the bends 33 can extend into the centering cup.

FIG. 9 shows another embodiment of the field shaper for an image display tube according to the invention in a cross section analogous to FIG. 3. For the sake of clarity, the reference numbers in this figure are again the same as in FIG. 3. In this embodiment, the gaps 35 are overlapped by plates 90 in accordance with the as yet unpublished Dutch patent application 8301712 (PHN 10674) on the side facing away from the electron beams. In this way, the shape of the horizontal field (the second deflection field) can be influenced. It is also possible to overlap column 34 in this way.

10a, b, c and d explain the effect of another type of field former for a color image display tube according to the invention. FIG. 10a shows a part of the vertical field, analogous to FIG. 7a, of which some field lines 100 are shown. Two curved field formers 101 and 102 are arranged in this field. The difference with FIG. 7a is that these are field formers for a so-called mini-neck tube with a neck diameter of approximately 22.5 mm and a mutual beam spacing of 4.4 mm, and the plates 103 that are closest to of the plane mentioned, are provided at their end facing away from the plane through the beam axes with angled flat plates 104 which, like the bends 105, extend inwards towards the central electron beam. It can be seen that the field lines 106 are additionally pulled outwards by the plates 104, as a result of which an even better pillow-shaped field is obtained. The bent plates are arranged on the wall of a centering cup with an inner diameter of 14.8 mm (not shown here). The Ab measurements of the plates can be derived to scale from FIG. 10a.

It can be seen from FIG. 10b analogous to FIG. 7b that the vertical field course is strongly pillow-shaped. To obtain the desired amount of vertical coma, the field formers 101 and 102 can be shorter in the direction perpendicular to the drawing plane of FIG. 10a than field formers without the angled plates 104 and 105. This shortening again results in lower horizontal field losses.

FIG. 10c shows a part of the horizontal field, some field lines 107 of which are shown. It can be seen from FIG. 10c and FIG. 10d analogous to FIG. 7d that the horizontal field is only slightly weakened by the angled plates 105 and 104 and the gap between the plates and is almost not distorted at the location of the electron beams.

Claims (6)

1. Image display tube with an "in-line" type electron gun in an evacuated flask to produce three electron beams with their axes in one plane, the axis of the center beam coinciding with the tube axis, which electron beams on a screen that is on is attached to a wall of the piston, converge and are deflected via this screen in two mutually perpendicular directions with the aid of a first and a second deflection field, the direction of the first deflection field being parallel to the plane of the electron beam axes mentioned, which electron gun system is bent at its end Field formers are provided which, as far as possible, cover the grids described by the electron beams on the screen, and each field former has at least two ferromagnetic plates which are essentially in extension from one another and are separated by gaps ischemic material, which are symmetrical with respect to the above-mentioned plane and the central tube axis, and the curved field formers with their hollow sides facing the three beams, which field formers make the first deflection field pillow-shaped at the location of the electron beams, characterized in that each Field formers, at least the plates which are furthest from the plane mentioned, are equipped at their end facing away from the plane mentioned with angled, essentially flat plates which extend in the direction of the central electron beam. 2. Color image display tube according to claim 1, characterized in that each field former contains four plates which are in an extension of one another and are symmetrical with respect to the plane mentioned and are separated by three columns. 3. Color image display tube according to claim 2, characterized in that the gap intersecting the plane is wider than the column above and below the plane. 4. Color image display tube according to claim 2 or 3, characterized in that in addition the plates which are closest to said plane are provided at their end facing away from said plane with angled flat plates which extend in the direction of the central electron beam . 5. Color image display tube according to one of the preceding claims, characterized in that the electron gun is provided at its end with a centering cup, wherein the mutually extending plates are attached to the inner wall or the outer wall of this centering cup. 6. Color image display tube according to one of the preceding claims, characterized in that at least one of the gaps between the plates is overlapped in a known manner on the side facing away from the electron beams at a distance from the plates of shunt plates.

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