JP2677585B2 - Image display device - Google Patents

Abstract

Picture display device having a display tube (3) and a deflection unit (9) comprising a field deflection coil and a line deflection coil (11). To comply with a predetermined interference radiation standard, the picture display device comprises a first set of (horizontal) interference suppression coils 18, 19 arranged symmetrically relative to the plane of symmetry of the line deflection coil and a further set of (vertical) interference suppression coils 18a, 19a arranged at right angles to the plane of symmetry of the line deflection coil, which coils are oriented in such manner and in operation are energizable in such manner that, measured at a predetermined distance from the picture display device, at least the strength of the local magnetic dipole field is below a desired standard. Each coil of the further set preferably comprises at least two sub-coils arranged parallel to each other at a given distance in order to reduce the energy content of the coil system.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an image display fluorescent screen, in which a rear portion is composed of a cylindrical neck portion which accommodates an electron beam generating device, and a front portion of which is the widest portion on the front side. With a funnel-shaped display tube, and with an electromagnetic deflection unit mounted around the display tube for deflecting the electron beam across the display screen, and when energized at least a dipole component. The present invention relates to an image display device including a line deflection coil and a field deflection coil that generate a magnetic field.

Recently, more stringent standards have been introduced for magnetic interference fields generated around the environment for certain image display devices, especially monitors. Until now, protective shields, such as, for example, a metal conical jacket for display tube and deflection unit pairs, have sometimes been used in image display devices, but such protective shields are generated by image display devices. The tendency is to prevent the influence of external magnetic fields on the display device rather than to reduce the magnetic interference field. The source of the magnetic disturbing magnetic field is the line deflection coil, because unlike the field deflection coil it operates at radio frequency currents (frequency in the region of 10 to 100 kHz). It is impossible to design a deflection coil that operates satisfactorily without generating stray magnetic fields. Even if the stray magnetic field is eliminated by means of a protective shield, and even if the display tube-deflection unit pair is also shielded at the display screen side, such a shield has little effect.

It is an object of the present invention to meet a given radiation (stray magnetic field) standard without the use of the shield means described above. According to the invention, the object in an image display device of the form described at the outset is that the display device is such that at least the local magnetic dipole field strength is measured at a predetermined distance from the image display device. A compensating coil system that is oriented to be below a predetermined standard and can be biased upon actuation, the compensating coil system being located opposite the facing surface of the line deflection coil outside the deflection unit. And a first part of the compensation coil which is axially extended for the most part
And a pair of separate compensation coils arranged opposite the line deflection coil on the outer side of the deflection unit and extending at least approximately parallel to the display screen. It

The invention is based on the recognition that for the suppression of disturbances of the magnetic field at long distances from the disturbance source (for example distances above 3 m), compensation of the dipole component alone is sufficient. The deflection units also generate higher order (eg 6-pole or 10-pole) magnetic deflection field components, but their intensity decreases more rapidly with distance than the intensity of the dipole component, so their contribution Is almost negligible at a distance of about 50 cm. The magnetic dipole moment from the disturbing source (line deflection coil) can be compensated by adding an opposite dipole moment. This dipole moment energizes the two current loops located on the outer side of the line-deflecting coil, and most of the two lengths of these loops are laterally oriented and at least approximately parallel to the tube axis. The current loop has a predetermined number of turns, a predetermined surface area, and a predetermined orientation. The energization is enabled by placing a compensating coil constituted by a current loop in series or in parallel with the line deflection coil.

The compensation coil should preferably cover as large a surface area as possible. The larger the surface area, the smaller the energy required to generate a given magnetic dipole moment. For example, a surface area of 1 to 10 dm ² has been found to be suitable in practice.

The number of turns in the compensation coil can be small (10 or less). In most cases 2 to 6 turns are sufficient. In order to reduce the disturbing magnetic field at a distance of about 50 cm, the compensating coil system according to the present invention is arranged outside the deflecting unit, opposite to the opposite face of the line deflection coil, and on the display screen. It comprises two separate compensation coils extending in parallel. During operation they should be energized in the same way as the first compensation coil.

As mentioned, the compensation coil must be large to reduce the energy volume.

However, various display devices (especially monitors) have a problem in that there is a lack of space for accommodating a large coil system at an accurate position. Therefore, a relatively small (too small) compensation coil needs to be used,
So much more energy (with line deflection) is consumed for radiation compensation. The space available for the coils arranged parallel to the display screen is often too small.

In a preferred embodiment of the image display device according to the present invention,
This problem is solved by having two separate compensation coils, each comprising at least two auxiliary coils arranged in parallel at a predetermined distance. Those effects will be described later.

The first compensating coil may be formed by looping the current in a generally coplanar manner, the turns of which are parallel to the counter face of the line deflection coil. However, it is practical to form them as saddle coils mounted outside the electromagnetic deflection unit. Especially when the saddle coils are of the so-called yoke winding type (ie wound on a support) they are such that two major parts of their length extend axially laterally facing the tube axis. Of which at least two coil windows of different size are defined, with the connecting part connecting them at their ends. By adjusting the surface area of the windows (and because of the "effective" coil surface altogether) it is possible to adapt the compensating dipole field to the stray field of each line deflection coil with which the first compensating coil is combined. Is.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1a is a perspective front view of a set of a deflection unit and a display tube mounted in a cabinet 12 equipped with a means for compensating for a disturbing magnetic field according to the present invention. For clarity, all unnecessary details for understanding the invention have been omitted.

The display tube has a cylindrical neck portion 1 and a funnel-shaped portion 3,
The widest part of section 3 is on the front side of the tube and comprises a display screen (not shown).

The display screen comprises a phosphor that emits a predetermined color depending on the penetration of electrons. The rear part of the neck 1 is equipped with an electron gun system (illustrated diagrammatically). An electromagnetic deflection unit 9 shown diagrammatically in the transition region between the neck 1 and the funnel-shaped portion 3 is arranged on the tube, which unit, among other things, a line deflection coil 11 for deflecting the electron beam in the horizontal direction x. (Item 1b).
As shown diagrammatically in FIG. 1b, the line deflection coil 11 may, for example, consist of two saddle-shaped coil halves. In the operating state, a sawtooth current having a frequency on the order of 10 to 100 kHz, for example about 6 kHz, flows through these coils. The line deflection coil 11 is generally surrounded by an annular core element 10 of soft magnetic material, a so-called yoke ring, which coil is shown in broken lines in FIG. 1b.

Assume that the line-deflecting coil is a current loop with a given magnetic moment at a long distance when the radiating field of the line-deflecting coil with the yoke ring faces the radiating magnetic field of the coil without the yoke ring initially at equal magnitude. You can

Magnetic field at the center of line deflection coil without yoke ring
B ₀ is calculated to be about 30 Gauss. The magnetic field of an actual deflection coil with a yoke ring is about twice this value.

The line deflection coil field is about 1 milligauss at a distance of 1 m.

This radiating field is compensated by means of an auxiliary loop current with a low nI value and a large diameter, which is the same as the magnetic moment of the coil itself. Such an auxiliary loop current can be generated by means of a compensation loop with a direct current R _c = 20 cm and a number of turns n _c = 4. In this way, for example, a 40 dB reduction is achieved at a distance of 3 m or more from the radiation source. The orientation of the compensation loop is at the planned distance (eg
The magnetic dipole moment generated in the current path through this coil must be oriented so as to compensate for the magnetic dipole moment of the disturbing component. For this purpose, the dipole moment of the compensation loop must be parallel and opposite to the dipole moment of the disturbing component. The first disturbing component is the line deflection coil. However, the line output transformer may also generate a disturbing magnetic field and is then considered a disturbing component. In that case:

Parallel dipole moments arising from one or more components can be compensated with one current loop. Non-parallel dipole moments are compensated in one loop when the dipole moments to be compensated are in phase and in frequency.

Thus a device with a large number of direct disturbance sources (line output stage, deflection coil) and a large number of indirect disturbance sources (reflector, substrate) compensates for magnetic stray fields with a limited number of turns and a given diameter. It is possible to compensate with a loop.

By choosing a low number of turns and a large surface area, the following conditions are always met.

1. Its magnetic dipole moment vector is equal to the sum of the dipole moments of all direct sources of the device.

2. The load on the power supply, the device itself, and especially the interference components of the deflection coil are sufficiently small.

Figure 2 shows a set of two disturbing coils, a set placed horizontally
Figure 18 shows a deflection unit with 18,19 and a set 18a, 19a arranged vertically. By choosing the number of turns of the vertically arranged set to be different from the number of turns of the horizontally arranged set, and by accurately selecting the current direction and magnitude of the horizontally and vertically arranged set, approximately A significant magnetic field reduction is achieved at a distance of 50 cm. Precise selection of the current direction is especially important when energizing the disturbance suppression coil system, in which the current in the horizontally arranged part flows in the same direction as the current in the corresponding (axial) part of the line deflection coil and vertically. It means that the current of the arranged part flows in the direction opposite to the direction of the corresponding (transverse) part of the line deflection coil.

The operation of the coil arrangement of FIG. 2 is described with reference to FIG. The disturbing magnetic field of the deflection coil 26 is roughly regarded as the dipole (coil 21) in the tube 27. The coil 22 arranged opposite to the opposite face of the line deflection coil of the deflection unit 26
Compensation is activated by 23 and. But with coil 22
The hexapole component is generated due to the distance ΔY ₁ between 23 and the quadrupole component is generated due to the distance ΔX. If the coils 22,23 move forward (decrease ΔX and hence quadrupole), ΔY ₁ increases and hence hexapole increases. For this reason ΔY ₁ remains small, and the hexapole can be reduced to a certain extent by increasing the diameter of coils 22 and 23, so ΔX is inevitable because the coil cannot be inserted into the tube. Increase to. The quadrupole, which is proportional to the coil size, the current through the coil and the distance ΔY ₂ , is generated mainly for the two vertical coils 24 and 25. The quadrupole and hexapole are neutralized by precisely combining the size of the coil and the current strength. As for the octupole, not all coils should be large enough to touch its measuring annulus, at which time octupoles and higher harmonics begin to appear.

As already mentioned above, it is important to have a large size of jamming suppression coil in relation to energy consumption. If this is not possible, the present invention builds a separate system coil from at least two auxiliary coils (28a and 28b and 29a and 29b in FIG. 4) which are placed at right angles to the anti-plane of the line deflection coil. Is solved. The auxiliary coils of each pair are placed a predetermined distance (ΔZ) from each other to ensure the presence of minimum mutual inductance. In the case of two auxiliary coils, each auxiliary coil pair has half the number of turns required for only one additional coil. This means that the inductance of a system with two pairs of auxiliary coils is half the inductance of one coil set. This results in a reduction in energy volume.

The saddle coils 18 and 19 may be so-called yoke winding type.
This means that they are wound directly on the support. The support may, for example, comprise two grooved flanges secured to the front and rear sides of the deflection unit. The position of the turn portion extending in the axial direction is fixed by the groove. For example, a universal flange (with grooves evenly distributed over the circumference) winds a compensation coil with two or more coil windows of different size, so that it can also be used in different deflection units. Can be used for In this way, an "effective" compensation coil surface area is applied to each line deflection coil with which the compensation coil is associated. Fifth
The figure is a schematic plan view of half 30 of a compensation saddle coil with three coil windows 31, 32 and 33 of different sizes.

[Brief description of the drawings]

1a shows a perspective front view of an image display device having a display tube, FIG. 1b shows diagrammatically an electromagnetic deflection unit having a line deflection coil, and FIG. 2 has two sets of compensation coils. Fig. 3 shows a perspective back view of the display tube shown in Fig. 3, Fig. 3 diagrammatically shows a coil-tube combination in longitudinal section with two sets of compensation coils, and Fig. 4 shows one set of compensation coils. And FIG. 5 shows a perspective rear view of a display tube with a set of double compensation coils and FIG. 5 shows a schematic plan view of the compensation coil half with three windows. 1 ... Cylindrical neck part, 3 ... Funnel part 7 ... Electron gun system, 9 ... Electromagnetic deflection unit 10 ... Ring core element, 11 ... Line deflection coil 12 ... Cabinet 18, 19 ... Horizontal Set of disturbing coils 18a, 19a …… set of disturbing coils arranged vertically 21 …… coil 22,23 …… compensating coil first set 24,25 …… two different compensating coils 26 ・ ・ ・… Deflection coil 27 …… Tube 28a, 28b, 29a, 29b …… Auxiliary coil 30 …… Half of compensation saddle coil 31, 32, 33 …… Coil window

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Francis Cass Maria Petras Pius Doumelnik Netherlands 5621 Beer Aindow Fen Frühne Bautzwech 1 (72) Inventor Adrien Jacob Frosov Netherlands 5621 Beer Aindofen Furune Bautz Wech 1 (56) References Special Table Sho 63-503106 (JP, A)

Claims (5)

(57) [Claims] 1. A funnel-shaped rear part having a cylindrical neck for accommodating an electron beam generating device, the front part of which has a widest part on the front side and an image display fluorescent screen. A line having a certain display tube and also having an electromagnetic deflection unit mounted around the display tube for deflecting the electron beam across the display screen, and for producing a magnetic field having at least a dipole component when energized. An image display device comprising a deflection coil and a field deflection coil, wherein the display device further comprises a predetermined value when at least the local magnetic dipole field strength is measured at a predetermined distance from the image display device. A compensation coil system oriented to be substandard and capable of being energized upon actuation, the compensation coil system comprising a line outside the deflection unit. A pair of compensating coils disposed opposite to the opposite surface of the directional coil and having a majority of their length extending axially, and the opposite surface of the line deflection coil outside the deflection unit. An image display device, comprising: two separate compensation coils which are arranged opposite to each other and which extend at least approximately parallel to the display screen. 2. A display device according to claim 1, characterized in that the two further compensation coils each comprise at least two auxiliary coils arranged in parallel at a predetermined distance. Image display device. 3. A display device according to claim 1 or 2, wherein the first set of compensation coils comprises saddle type coils mounted on an electromagnetic deflection unit. Display device. 4. The display device according to claim 3, wherein the saddle-type coil has two major portions of their lengths, the side surfaces facing each other in the axial direction of the tube axis and extending from the deflection unit. An image display device, characterized in that it defines at least two coil windows located on the outside, most of which together with their connecting parts and of different sizes, connecting them at their ends. 5. The image display device according to claim 4, wherein the saddle type coil is a yoke winding type.