EP0523322B1 - Compensation of the electrical alternating field at the face of cathode ray picture tubes - Google Patents

Description

The invention relates to a method for compensating the electrical alternating field on the front surface of cathode ray picture tubes, to which a high voltage with a portion of alternating voltage is supplied from a high voltage generator via an EHT high voltage connection, and to a device which is suitable for carrying out the method.

In many countries there are protective regulations and recommendations for users of cathode ray picture tubes, which are used, for example, in televisions and video devices or as data terminals and monitors in data processing devices, to the effect that in these picture tubes the alternating electrical field outside the device must not exceed a certain limit value. At a distance of 30 cm from the front surface of the picture tube Frequency range from 2 kHz to 400 kHz not more than 1 V / m, in the frequency range from 5 Hz to 2 kHz not more than 10 V / m. If no special measures are taken to compensate for or at least weaken the electric field, the field strength recorded in this area can be at least a few 10 V / m.

It is known to weaken the alternating electric field by placing a glass plate in front of the front surface of the picture tube, which is covered with a low-resistance layer, via which the charges occurring through the alternating field flow away, so that its effect is largely canceled. However, the image quality is reduced by such a glass plate, which is a considerable cost factor.

In principle, it is also possible to weaken the internal alternating voltage of the picture tube, which is responsible for the alternating electrical field. The high-frequency components of this alternating voltage derive from the deflection frequency and its harmonics, in particular from the capacitive coupling with the rectifier for the high-voltage generator, hereinafter also referred to as the EHT generator, and from the capacitive coupling of the deflector coils; low-frequency components are caused by current fluctuations in the picture tube and the internal impedance in the EHT generator. These frequencies can be decoupled by means of a capacitor, but this is impractical if the strength of the alternating electric field must not exceed the low required limit value of 1 V / m at 30 cm distance in front of the picture tube, since this would require a large external capacitor.

EP-A 0 498 589 describes a method and a device for reducing the alternating current field which is generated by a cathode ray tube in its vicinity. A voltage with opposite polarity is applied to the anode of the cathode ray tube, which voltage is intended to compensate for the alternating current field. With this method, however, only some of the influences on which the alternating current field in the vicinity of the cathode ray tube is based can largely be eliminated.

EP-A 0 500 349 claims, among other things, the priority of 5.4.1991 (JP-73 236/91), which relates to FIGS. 1 to 8, 17, 18 and the corresponding parts of the description of this subsequently published document. From EP-A 0 500 349 a method and a device for compensating the alternating electrical field on the front surface of cathode ray picture tubes is known, to which a high voltage with a portion of alternating voltage is supplied from an high voltage generator via an EHT high voltage connection, the AC voltage is sensed on the connecting line between the high-voltage generator and the EHT high-voltage connection, the AC voltage is amplified and inverted and the AC voltage thus inverted is applied to at least one external electrode provided in the immediate vicinity of the picture tube. However, this circuit cannot be universally adapted to different electrodes, which are desirable for different cathode ray picture tubes for optimal compensation.

The object of the invention is therefore to provide a method which provides for a simple and effective compensation for the alternating electrical field on the front surface of cathode-ray picture tubes, and to provide a device with which the alternating electrical field can be compensated for and in particular for Carrying out the method is suitable.

This object is achieved by a method according to claim 1 and an apparatus according to claim 2.

Adequate compensation of the alternating electrical field can be achieved using this method or this device. This compensation is based on two effects, namely on the one hand that the internal AC voltage is reduced, and on the other hand that the electrical AC field generated by the remaining internal AC voltage is weakened by linear superposition with the field of the inverted AC voltage. Both effects together result in the desired compensation of the electrical alternating spring.

According to the invention, the gain of the inverting amplifier can be regulated, so that an optimal adaptation for the respective picture tube and external electrode is possible.

The external electrode or the external electrodes are expediently arranged outside the front surface of the cathode ray picture tube.

It is advantageous if the external electrode (s) at least partially surrounds the front surface of the cathode ray picture tube. It can thus be achieved that the inverted alternating voltage produces an alternating field which also uniformly covers the front surface of the cathode ray picture tube, so that compensation is optimally possible.

Different possibilities are conceivable for the formation of the external electrode, each of the forms of training mentioned below being able to be used individually or in combination with others.

The external electrode can be, for example, a ring electrode arranged outside the front surface of the cathode ray picture tube. A separate component is required here, but this has the advantage that the formation of the inverting field can be influenced as desired.

A binding tape surrounding the cathode ray picture tube can also be used as the external electrode. This binding tape is present anyway, so that apart from the necessary feed lines, no further structural measures have to be taken on the cathode ray picture tube.

It has the same advantage if the Aquadag region of the cathode ray picture tube is used as the external electrode.

This Aquadag area usually consists of a colloidal graphite-water dispersion that has electrically conductive properties.

Depending on the design of the electrode and the type of electrode used, it is necessary to amplify the AC voltage component that is tapped at the EHT high-voltage connection differently. If, for example, an outer electrode is used as the external electrode, the compensation effect is mainly based on the superimposition of the field generated from the inverted AC voltage, and the proportion of the compensation which is attributable to the reduction in the internal electrical AC voltage is comparatively small. A large amplification of the AC voltage is therefore necessary in order to be able to generate the large electrical AC field required for the compensation.

A metallic sleeve, in particular a copper sleeve, surrounding the connecting line between the high-voltage generator and the EHT high-voltage connection is provided for sensing or removing the AC voltage.

According to a further preferred embodiment of the present invention, which is particularly suitable when the Aquadag area is provided as the external electrode, a low-pass filter can be arranged in the connecting line between the high-voltage generator and the EHT connection, the output of which has a capacitance with the input of the Inverting amplifier is connected, wherein an output of the inverting amplifier is fed back to the output of the low-pass filter.

Fig. 1

eine schematische Darstellung einer ersten Ausführungsform einer Vorrichtung gemäß der vorliegenden Erfindung mit einer Kathodenstrahl-Bildröhre;

Fig. 2

eine Anordnung ähnlich der aus Fig. 1, wobei eine Abtastvorrichtung ebenfalls schematisch dargestellt ist;

Fig. 3

eine schematische Darstellung einer zweiten Ausführungsform einer Vorrichtung gemäß der vorliegenden Erfindung mit einer Kathodenstrahl-Bildröhre; und

Fig. 4

eine schematische Darstellung einer dritten Ausführungsform einer Vorrichtung gemäß der vorliegenden Erfindung mit einer Kathodenstrahl-Bildröhre.

In the following, the invention will be explained in more detail by way of example only with reference to the accompanying drawings. It shows:

Fig. 1

is a schematic representation of a first embodiment of a device according to the present invention with a cathode ray tube;

Fig. 2

an arrangement similar to that of Figure 1, wherein a scanning device is also shown schematically.

Fig. 3

is a schematic representation of a second embodiment of a device according to the present invention with a cathode ray tube; and

Fig. 4

is a schematic representation of a third embodiment of a device according to the present invention with a cathode ray tube.

1 shows a commercially available cathode-ray picture tube 1. This has a high-voltage connection, the so-called EHT connection 10, through which an internal electrical AC voltage is led out of the interior of the picture tube 1. A high-voltage generator 2 is also provided for the picture tube 1 and is connected directly to the EHT connection 10. A connection of a capacitor 4 is placed on the connecting line 5 between the high-voltage generator 2 and the EHT connection 10. The voltage thus tapped off at the EHT connection 10 is thus fed to an inverting amplifier 3 via the capacitor 4, which only allows the AC voltage component to pass through. Both the high voltage generator 2 and the inverting amplifier 3 are grounded. The output variable of the inverting amplifier 3 is fed to a ring electrode 12 which surrounds the front surface 11 of the picture tube 1. The ring electrode 12 is arranged so that it lies outside the field of view of the picture tube.

Via such an outer electrode 12 surrounding the front surface 11 of the picture tube 1, the high-frequency can advantageously Share of the AC voltage can be compensated. The amplitude of the AC voltage is not very high, for example it has peak-peak values of approximately 35V.

There are different ways of taking off the required AC voltage component, which is then to be fed to the inverting amplifier 3. However, this must always be done on the connecting line 5 between the high-voltage generator 2 and the EHT connection 10.

An example of a scanning device which is designed for this purpose is shown in FIG. 2 for the arrangement according to FIG. 1. A copper sleeve 6 is placed around the connecting line 5 between the high-voltage generator 2 and the EHT connection 10. The representation in the figure is only schematic and does not reflect the true proportions. On the outside of the copper sleeve 6, a line 7 is provided which leads to the inverting amplifier 3. The circuitry structure otherwise corresponds to that of FIG. 1.

In many picture tubes, in addition to the high-frequency AC voltage already mentioned, there is a low-frequency component which is indirectly attributable to the presence of the Aquadag area. A capacitance is formed between the EHT electrode 10 and the Aquadag region 14, through which internal current fluctuations are discharged from the picture tube. These proportions can also be compensated according to the invention.

FIG. 3 shows an arrangement of picture tube 1, high-voltage generator 3, inverting amplifier 3 and capacitor 4, which essentially corresponds to that of FIG. 1. In its area facing away from the front surface 11, the picture tube 1 is provided with an Aquadag area 14. As described above, the AC voltage component is on the connecting line 5 tapped or sensed of the high voltage and given on the one hand via line A to the ring electrode 12 and further via a line C directly to the Aquadag area 14.

The voltage fluctuations in connection with the Aquadag range represent the low-frequency portion of the interfering alternating voltages, the amplitude of which, however, is comparatively large. The peak-peak value can be up to 100V.

As shown in FIG. 4, one possibility is to connect a low-pass filter 8 of suitably matched resistance and capacitance into the connecting line 5 between the high-voltage generator 2 and the EHT connection 10 of the picture tube 1. The output of the low-pass filter leads via a capacitance 4 to the input of the inverting amplifier 3. An output of the inverting amplifier 3 is in turn fed back to the output of the low-pass filter 8. As before, a second exit is connected to the Aquadag area 14.

In principle, the output variable can be fed via a line to the binding tape 13, which, like the outer electrode 12, is arranged around the front surface 11 of the picture tube 1.

All of these measures can be used individually or in any combination with one another. Which option is actually implemented largely depends on the type of picture tube to be compensated for. Different solutions can be chosen, depending on whether a monochrome tube or a color image tube is available, the size of the front surface plays a role as well as the inner construction of the image tube. Different solutions can arise, depending on whether the technical or the economic optimum is sought.

For example, it has been shown that it is not possible with 14 "monochrome picture tubes because of the special type of grounding of the Aquadag area to give any signal thereon. It has proven to be expedient here to use a ring electrode surrounding the front surface On the other hand, good results have been obtained for color picture tubes of the same size by using a suitably dimensioned low-pass filter and applying a low-frequency AC voltage to the Aquadag range as described above.

Reference list

1

Cathode ray tube

2nd

High voltage generator

3rd

Inverter amplifier

4th

capacitor

5

Connecting line

6

Copper sleeve

7

management

8th

Low pass filter

10th

EHT connection

11

Front surface

12th

Ring electrode

13

Binding tape

14

Aquadag area

Claims (9)

1. A method for compensating the electrical alternating field at the face of cathode ray picture tubes to which a high-voltage having a portion of alternating voltage is supplied by a high-voltage generator through an EHT high-voltage terminal, in which method said alternating voltage is sampled on the connecting line between high-voltage generator and EHT high-voltage terminal, alternating voltage is amplified and inverted by an inverting amplifier having controllable-gain and the amplified inverted alternating voltage is supplied to at least one external electrode provided in close vicinity of the picture tube, wherein the gain of the alternating voltage is adjustable to the external electrode which is used for the cathode ray picture tube.
2. A device for compensating the electrical alternating field at the face of cathode ray picture tubes, to which a high-voltage having a portion of alternating voltage is supplied by a high-voltage generator via an EHT high-voltage terminal, in particular for performing the method of claim 1, comprising an inverting amplifier circuit (3) for alternating voltage having an input for such alternating voltage which is taken from a connecting line (5) between high-voltage generator (2) and EHT high-voltage terminal (10) and having controllable gain wherein in close vicinity of the picture tube (1) at least one external electrode (12, 13, 14) is provided to which the inverted alternating voltage with adjusted gain is supplied.
3. The device of claim 2, characterized in that said external electrode(s) (12, 13, 14) is/are arranged outside the face (11) of said picture tube (1).
4. The device of claim 2 or 3, characterized in that said external electrode(s) (12, 13, 14) at least partially surround(s) the face (11) of said picture tube (1).
5. The device of any of claims 2 to 4, characterized in that at least one of said external electrodes is a ring electrode (12) arranged outside the face (11) of said picture tube (1).
6. The device of any of claims 2 to 4, characterized in that at least one of said external electrodes is a framing strip (13) surrounding said picture tube (1).
7. The device of any of claims 2 to 4, characterized in that at least one of said external electrodes is the aquadag zone (14) of said picture tube (1).
8. The device of any of the preceding claims, characterized in that a metal sleeve (6), in particular a copper sleeve, which at least partially surrounds said connecting line (5) between high-voltage generator (2) and EHT high-voltage terminal (10), is provided for sampling or taking off the alternating voltage therefrom.
9. The device of any of the preceding claims, characterized in that a low pass filter (8) is arranged in said connecting line (5) between high-voltage generator (2) and the EHT high-voltage terminal (10), the output thereof being connected to the input of said inverting amplifier circuit (3) through a capacity (4), wherein an output of said inverting amplifier circuit (3) is fed back to the output of said low pass filter (8).

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