EP1376646A2 - Funnel for cathode ray tubes - Google Patents

Abstract

The main screen section of the cathode ray tube expands out from the throat to a parabolic section. In end view the section has a general rectangular profile and defines the electron beam region (6). However the sides are formed with a concave profile (3e,3d). This provides an optimum condition for beam projection.

Description

The invention relates to a funnel for a cathode ray tube, with a a funnel area forming a funnel area with one at its tip molded parabolic area and with a funnel neck on the parabola area is attached, the parabolic area in at least one section one between the connection points to the funnel neck and to the funnel body rectangular, otherwise essentially round cross-section, and the inner contour of the wall of the rectangular parabolic section is arched inwards on all four sides.

Such a funnel is known for example from WO 98/07174 A2.

Cathode ray tubes are widely used for televisions and Displays used for computers. They consist of a glass funnel that together with the screen the evacuated space of the cathode ray tube forms.

The funnel itself is divided into three areas: the neck, the Contains electron beam gun and is cylindrical; the Parabola area around which the deflection coil for guiding the Electron beam is arranged and the round, growing Has cross-sectional area; the funnel body, its cross-sectional area increases steadily and changes from a round to a rectangular shape until the cross-sectional area of the screen has been reached. Is under a rectangle to understand an area that is substantially rectangular, but can have rounded corners.

According to the rectangular shape of the screen, the area of the Area that is swept by the electron beam, rectangular. this leads to to the fact that in the area of the funnel in which its cross section is round, especially in the parabolic area, a large proportion of the area is not used becomes. Since also the deflection coil unit for guiding the Electron beam attached outside of the funnel in its parabolic area is a large part of the energy (about 25%) that of the deflection coil unit is supplied for overcoming the distance to Electron beam can be used by the magnetic field.

EP 0 813 224 A2 discloses a glass funnel for To use cathode ray tubes, the cross-sectional area only in the Funnel neck is round, and which is already rectangular from the parabolic area. This ensures that the unused area is reduced and the Deflection coil can be attached closer to the electron beam. this leads to considerable energy savings. The disadvantage of what is proposed there rectangular parabola area, however, is that the This makes the cathode ray tube very implosion-prone. To the Geometry of the glass funnel or the way the Cross-sectional area increases and in what way they at the beginning of the Parabolic area becomes rectangular, so very tight conditions established. This is the only way to ensure adequate security against implosion guarantee. There is also a disadvantage from a production point of view in the fact that with the introduction of this new form of parabola entire manufacturing process must be changed, since the proposed Glass funnel shape differs greatly from the standard shape.

A funnel for cathode ray tubes is known from DE 199 22 225 C1 that makes it possible to save energy while using conventional However, the funnel body is as implosion-proof as possible. This happens through a glass funnel for cathode ray tubes, the one funnel neck, the is cylindrical, a funnel body, the cross section of one round shape changes into a rectangular shape, the cross-sectional area grows continuously, as well as having a parabolic area between the funnel neck and the funnel body is arranged and its Connection cross sections both to the funnel body and to the funnel neck in the are substantially circular, and which is characterized in that the Parabola area in at least one section between the connection points a rectangular cross-section to the funnel neck and the funnel body having.

Due to the rectangular cross-section in the central area of the parabola, the Glass outer contour of the funnel on the small and large axis closer to the Funnel central axis brought. The length of the area with rectangular Cross-section moves in the centimeter range. Because the deflection coil unit sits directly on the glass outer contour of the funnel the deflection coil unit is brought closer to the electron beam that is inside of the funnel runs. The magnetic field generated by the deflection coil unit is built up for guiding the electron beam, must therefore be less Overcome distance and can be less strong. This will make electrical Energy saved.

The greater the distance from the source of a magnetic field, the greater also the distance of the field lines. Now that the magnetic field of the Deflection coil unit is closer to the electron beam and therefore the Field line density compared to the field line density in standard parabolic areas the beam can be guided more precisely.

The glass funnel known above can be used in both 4: 3 and 16: 9 Realize the format that is common today. The The greater the energy saving effect, the more important it is Deflection angle is what's especially on cathode ray tubes in 16: 9 screen format true. This effect is particularly great Deflection angles of 120 ° and larger.

As a result, as seen on the overall glass funnel, the funnel shape opposite conventional glass funnels only in a small area, the middle Area of the parabolic area is changed, the implosion security only slightly deteriorated. It turned out that the tension, that occurs in the glass, in the transition area between the funnel neck and Parabolic area most elevated. But even there is only one Percent change. So there are no additional precautions to increase the security against implosion.

This advantageously corresponds to the previously known funnel Aspect ratio of the rectangular cross section of the parabola area Aspect ratio of the rectangular cross-section of the funnel body at its end opposite the funnel neck. At this end the Funnel body the aspect ratio of the screen. Since the Electron beam can also cover an area with this aspect ratio the deflection coil are attached so that they are as close as possible from all sides is arranged on the electron beam when the parabola region in the Section with a rectangular cross section also this aspect ratio having.

The cross-sectional area of the parabolic area preferably grows continuously on. The is preferably over the entire parabola area Diagonal of the cross-sectional area continuously longer.

The rectangular parabolic area of the funnel known above has one Inner contour that is curved to the funnel center axis jin; the associated In contrast, the outer contour is linear. A corresponding configuration of the The parabola area of the funnel also show US 6,255,766 B1 and that Japanese Patent Abstract No. 111 209 39 A and US-A-5,929,559 (Fig. 5).

This configuration creates a relatively large one in the side areas Wall thickness so that the minimization of the distance between the Deflection coil unit and the area swept by the electron beam is limited.

The object of the invention is based on a funnel of the aforementioned DE 199 22 225 C1 to train this so that a still smaller distance between the deflection coil unit and that of Electron beam swept area is achievable, i.e. an even smaller one Distraction energy is necessary.

A funnel for solves this problem Cathode ray tubes with a funnel body Funnel area, with a parabolic area and with a funnel neck attached to the parabola area, the Parabola area in at least one section between the connection points a rectangular to the funnel neck and the funnel body, otherwise one has a substantially round cross section, and the inner contour of the Wall of the rectangular parabola section on all four sides inwards is curved, according to the invention in that the outer contour of the Wall of the rectangular parabola section on all four sides, the Inner contour to form a double concave structure on all sides Wall is spaced substantially parallel following, is curved inwards.

The double concave cross-sectional configuration according to the invention results there is a very small distance between the deflection coil unit and Electron beam and thus a significantly minimized deflection energy. Further the above configuration causes the wall thicknesses to not change significantly change what advantages in terms of voltage distributions and due to manufacturing.

The aforementioned US-A-5,929,559 also shows two embodiments, where either the outer contour parallel to the small axis or parallel can be arched inwards to the major axis. However, this follows in this Areas of the outer contour are not parallel to the associated inner contour Distance because the curvature of the outer contour is significantly smaller than that is the inner contour. This creates again in the side areas of the rectangular parabola section relatively large wall thicknesses with maximas in the middle of the side areas, which once minimized the Distance between the deflection coil unit and that of the electron beam area is limited and on the other hand the described Disadvantages with regard to the stress distribution and the production ultimately remain.

Embodiments of the invention are characterized in and are also shown in the description of the figures.

An embodiment of the invention is based on that in the patent drawing illustrated figures explained.

Figur 1

einen Querschnitt durch den rechteckigen Bereich des Parabelbereiches eines Trichters nach Fig. 2 mit einer doppelkonkaven Konfiguration nach der Erfindung,

Figur 2

einen Längsschnitt durch einen halben Glastrichter mit Bildschirm,

Figur 3

einen Querschnitt durch einen herkömmlichen Parabelbereich mit rundem Querschnitt, und

Figur 4

einen Querschnitt durch einen Parabelbereich mit rechteckigem Querschnitt nach dem Stand der Technik.

Here shows:

Figure 1

3 shows a cross section through the rectangular region of the parabolic region of a funnel according to FIG. 2 with a double-concave configuration according to the invention,

Figure 2

a longitudinal section through half a glass funnel with a screen,

Figure 3

a cross section through a conventional parabolic area with a round cross section, and

Figure 4

a cross section through a parabolic area with a rectangular cross section according to the prior art.

In Figure 2 is the upper half of a longitudinal section through a glass funnel 1, which is connected to a screen 5 by soldering. The glass funnel 1 consists of a funnel neck 2, a parabolic area 3 and a funnel body 4. In the funnel neck 2 is a not shown Electron gun arranged. Around the parabola area 3 is in the usual way a deflection coil 8 is arranged. The funnel neck 2 is cylindrical throughout trained and as a separately manufactured part at one end of the Parabola area melted. The parabola area 3 points in the transition to Funnel neck 2 and a one-piece transition to the funnel body 4 circular cross-sectional area and has a rectangular in between Cross-sectional area that grows continuously and its diagonal is getting longer and longer. The funnel body 4 points in the transition to Parabolic area 3 has a circular cross-sectional area, but the Screen becomes rectangular and grows continuously. This corresponds to the aspect ratio of the rectangular cross section of the parabola area Aspect ratio of the rectangular cross-section of the funnel body at its end opposite the parabola. In addition, in FIG Area 6 shown that the electron beam around at maximum deflection covers the angle α, as well as the area 7, which is thereby of the Electron beam is not covered.

The section through the parabola area 3 along the line I-I of FIG. 2 is in Figure 4 shown. It can be seen that with a parabola area 3c rectangular cross section of area 7, which is not from the electron beam is covered, is significantly lower. The transformation of the parabola area 3c with a rectangular cross-section virtually forms the border of area 6, which is covered by the electron beam. This means that the deflection coil 8 can be arranged in close proximity to the electron beam and the Sufficient electron beam with a magnetic field of lower energy can be distracted.

In Figure 3 is the cross section corresponding to Figure 4 through a conventional parabola area with a round cross section 3 b shown. The area 7 not covered by the electron beam now makes a large part of the total cross-sectional area. Only in the corners of the area 6 covered by the electron beam is the distance between Electron beam and deflection coil ideally small.

The invention builds on the known screen with a rectangular parabolic part according to FIG. 4. The main aim of the invention is to minimize the deflection energy required in order to save costs and do justice to environmental protection. The starting point of the invention was the finding that the cross section of the surface 6 swept by the electron beam in the region of the deflection coil 8 is not exactly rectangular, but is concave in shape.
Only when the electron beam leaves the influence of the deflection coil does the electron beam cross-section change its shape until it finally has a rectangular cross-section when it hits the screen.

4, it is known that the inner contour 3 d of the rectangular Parabolic section to the area 6 swept by the electron beam is domed, i.e. seen from the outside has a concave contour. The The outer contour 3 e of the parabola, on the other hand, is linear. By doing it The resulting relatively large wall thickness is the minimization of the distance between the deflection coil 8 and that swept by the electron beam 6 Area limited. This distance can be further minimized if as shown in Fig. 1, the outer contour 3 e of the parabola to the inside is domed, i.e. seen from the outside also has a concave contour. It this creates a double concave cross section.

The concave-shaped outer contour 3 e, which follows the inner contour 3 d at a substantially parallel distance, has the advantage of not having a significantly changed distance from the inner contour, so that the wall thicknesses do not vary significantly.
Almost the same wall thickness advantageously means more uniform cooling in the parabolic area and thus more favorable stress distributions in the glass.
Furthermore, the cold room design of the tools can be designed more simply due to the almost constant wall thickness. Complicated contours in the tool, which are always required when the wall thicknesses are very different, are eliminated here. In addition, there is the essential advantage of the even smaller distance between the deflection coil and the electron beam. This small distance means that the energy required to deflect the electron beam can be reduced even more than in the known case according to FIG. 4.

The invention therefore ultimately comprises a funnel for one Cathode ray tube, its parabola attached to the concave shaped electron beam is optimally adapted.

The double concave cross section can completely deviate from the parabola Funnel body 4 to the end of the parabola at the base of the funnel neck 2 extend. However, it can also be only partially double-concave, should however extend to at least 50% of the parabola height. The 1 changes over the Parabola height not essential.

Investigations regarding the influence of strength of the double concaves Parabola through the finite element analysis showed that the strength at no too strong a 3-radius contour is not permanently impaired. The diagonal presents itself as a kind of stiffening rib, based on the stability of the parabola has great influence. If the 3-radius contour is too pronounced, there is one strong voltage range, but with a softer 3-radius contour can be compensated.

The parameters which are decisive for the formation of the parabola section 3 are entered in FIG. 1. Mean: R _A outer radius Big axis R _B inner radius Big axis R _c outer radius Small axis R _D inner radius Small axis R _E outer radius diagonal R _F inner radius diagonal D _K wall thickness Small axis D _G wall thickness Big axis D _D diagonal

The relationship D _K D _D D _D D _G applies to the wall thicknesses, ie the diagonal wall thickness should be greater / equal in the parabolic part according to the invention than in the minor axis and less / equal than in the major axis. The diagonal wall thickness is the wall thickness in the corners of the rectangle, the small axis runs along the narrow side and the large axis runs along the long side of the rectangle. The wall thickness D _K in the longitudinal side area of the rectangle is preferably smaller than the wall thickness D _G in the narrow side area.

The penetration points of the radii R _A , R _B , R _C, R _D should lie outside the parabolic cross section. This ensures a concave outer shape.

The penetration points of the radii R _E and R _F should lie within the parabolic cross section. This ensures a concave inner contour.

For a funnel type 76 FW with a diagonal dimension of 811.6 mm, the following parabolic dimensions result: D _K 4.98 mm D _D 5.20 mm D _G 5.68 mm R _A 70 mm R _B 223 mm R _C 257 mm R _D 140 mm R _E 10 mm R _F 8.5 mm

The outside dimension in the diagonal is 43.3 mm.

Claims (7)

Funnel (1) for cathode ray tubes, with a funnel area (4) forming a funnel body, with a parabola area (3) formed on the tip thereof and with a funnel neck (2) attached to the parabola area, the parabola area (3) in at least one The section between the connection points to the funnel neck (2) and to the funnel body (4) has a rectangular cross-section, moreover a substantially round cross-section, and the inner contour (3 d) of the wall of the rectangular parabolic section is curved inwards on all four sides, characterized in that the outer contour (3 e) of the wall of the rectangular parabolic section is curved inwards on all four sides, following the inner contour to form an all-round double-concave structure essentially parallel to the wall, inwards. Funnel according to claim 1, characterized in that the radius of curvature of the inner contour is coordinated with the radius of curvature of the outer contour so that the wall thickness of the rectangular parabolic section in the side areas is substantially the same. Funnel according to claim 1, characterized in that the wall thickness (D _K ) in the longitudinal side area is smaller than the wall thickness (D _G ) in the narrow side area of the rectangle. Funnel according to one of claims 1 to 3, characterized in that the double-concave structure of the wall extends to at least 50% of the parabolic area. Funnel according to claim 4, characterized in that the double-concave structure of the wall extends completely from the parabolic attachment on the funnel body (4) to the attachment of the funnel neck (2) on the parabolic area (3). Funnel according to one of claims 1 to 5, characterized in that the parabolic region is shaped such that the diagonal wall thickness is greater / equal than the wall thickness on the minor axis and less than / equal to the wall thickness on the major axis. Funnel according to one of claims 1 to 6, characterized in that the parabolic region (3) has an essentially round connection cross section both towards the funnel body (4) and towards the funnel neck (2).

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