DE29721276U1 - Monochrome monitor - Google Patents

Description

GR 97 G 4459 EN

Description
Monochrome monitor

The invention relates to a monochrome monitor with a deflection unit and a cathode ray tube having a tube neck and a screen.

In high-resolution monochrome monitors, e.g. in monitors with a resolution of 2000 x 2500 pixels, measures are required to correct astigmatic imaging errors. Such imaging errors occur when, for example, a circular beam cross-section is displayed as an ellipse on the screen of a monitor, which means that the deflection process in the monitor's deflection unit distorts the image.

From EP 0 516 229 B1 a display device with a color display tube with means for convergence correction is known. A convergence correction device has a flexible carrier which is wound around the tube neck. The carrier comprises a first and a second coil system, each of which extends over an angle of 360° and each of which has a number 2N, N = 2, 3 ... of coreless coils which together, when excited, generate a magnetic 2N pole field, N = 2, 3 ..., in order to shift the outer beams in relation to the central beam.

The present invention is based on the object of largely avoiding astigmatic imaging errors on the screen of a monitor of the type mentioned at the beginning.

This task is solved by fitting a flexible support around the tube neck in front of the deflection unit to correct astigmatic imaging errors on the screen.

GR 97 G 4459 EN

wound, which comprises a first coil system on its top side and a second coil system on its bottom side, each of which contains a number 2N, ■ N = 2, 3 ... core-free coils that are excited by a correction current and thereby together generate a 2N pole field, N = 2, 3 ..., in order to largely compensate for the direction-dependent different focusing effect of the deflection fields generated by the deflection unit.

The invention is based on the idea of deliberately deforming the cross-section of the beam before the electron beam is deflected by the monitor’s deflection unit in order to compensate for the deformation caused by the deflection.

In one embodiment of the invention, an amorphous metal strip is wound around the flexible carrier, which causes a magnetic short circuit, whereby only a small correction current is required to excite the coils.

The invention, its embodiments and advantages are explained in more detail below with reference to the drawing, in which an embodiment of the invention is illustrated.

Show it:

Figure 1 Components of a cathode ray tube in schematic representation,

Figure 2 a coil carrier,

Figure 3 shows a first and a second coil system and Figure 4 shows the circuit diagram of a first and a second coil system.

In Figure 1, 1 denotes a glass bulb of a cathode ray tube, which comprises a tube neck 2 and a funnel-shaped part 3, which is provided with an anode connection 4. An inner coating of the glass bulb 1 consists of a

GR 97 G 4459 EN

electrically conductive coating, ζ. B. from an aluminum layer 5, which serves to divert the electrons emitted by a cathode 6 to a luminescent layer 7. In the tube neck 2 there is an electron beam generator, which consists of the cathode 6, a control grid 8, a screen grid 9 and a focusing unit 10. A deflection unit 11 with horizontal and vertical deflection coils is provided for the periodic deflection of an electron beam (not shown here) generated by the electron beam generator in the horizontal and vertical directions. The deflection field 2N, N = 2, 3 ... generated by the deflection unit 11 causes a focusing effect on the electron beam with varying degrees of intensity depending on the deflection direction, which creates astigmatism. In order to compensate for this effect to a large extent, a flexible carrier 12 is wound around the tube neck 2 in front of the deflection unit 11, which comprises a first coil system on its upper side and a second coil system on its lower side, each of which contains a number 2N, with N = 2, 3 ..., of core-free coils that are excited by a correction current and thereby together generate a 2N pole field, N = 2, 3 ....

In the following, reference is made to Figure 2, in which a flexible coil carrier is shown.

The coil carrier consists of a flexible circuit board 14 provided with a connecting cable 13, on which a first and second coil system (not shown here) is arranged and which is wound around a tube neck 15. The flexible circuit board 14 is enclosed by an amorphous metal band 16, which causes a magnetic short circuit, whereby only a small correction current is required to excite the coil systems.

The first and second coil systems are offset by an angle of 45° (Figure 3) and each have four core-free

GR 97 G 4459 DE ·♦ · * »» ♦ * *-*»*

Coils 17, four of which are arranged on the top side 18 and four on the bottom side 19 of the flexible circuit board, wherein the bottom side 19 is insulated from the top side 18 and the flexible circuit board is glued with the bottom side 19 to the tube neck.

Figure 4 shows the circuit diagram of a first and a second coil system, each of which extends over an angle of 360° and each of which has four coils 20a, 20b, 20c, 20d; 21a, 21b, 21c, 21d. The first and second coil systems are each supplied with a correction current via first and second connections 22, 23, whereby the coils 20a..., 21a... together generate a 4-pole field, such that the direction-dependent different focusing effect of the deflection fields generated by a deflection unit of a cathode ray tube is largely compensated.

Claims (3)

GR 97 G 4459 DE /r t* #« t#e ,♦«.♦·«♦ Protection claims 1. Monochrome monitor with a deflection unit (11) and a cathode ray tube having a tube neck (2) and a screen, characterized in that, to correct astigmatic imaging errors on the screen, a flexible carrier (12; 14) is wound around the tube neck (2) in front of the deflection unit (11), which comprises a first coil system on its top (18) and a second coil system on its bottom (19), each of which contains a number 2N, with N = 2, 3 ..., core-free coils (17; 20, 21) which are excited by a correction current and thereby together generate a 2N pole field, with N = 2, 3 ..., in order to largely compensate for the direction-dependent different focusing effect of the deflection fields generated by the deflection unit (11). 2. Monochrome monitor according to claim 1, characterized in that an amorphous metal strip (16) is wound around the flexible carrier (12; 14). 3. Monochrome monitor according to claim 1 or 2, characterized in that the first and second coil systems are offset by 45° and are each provided with four coils (17; 20, 21).