DE2801916A1 - TELEVISION TUBE - Google Patents

Description

DESCRIPTION

The invention relates to electron guns, particularly those for television picture tubes.

In a known type of color television picture tube, a high voltage of 25 to 30 kV is applied to a final accelerating electrode an electron gun and a screen applied via an anode button on the funnel part the picture tube is arranged. At the same time, a voltage of 0-5 kV is applied to a focusing electrode, which an electron lens serving for focusing forms, which is arranged near the last acceleration electrode is via one at the end of a neck portion of the Picture tube arranged connection pin.

To create a small spot of light on the screen so that a more accurate and sharper image is created, it is Desired to keep the aberration of the focusing lens as low as possible, For this purpose it is necessary to use the To reduce voltage gradients between the electrodes. For this it is possible to adjust the distance between the electrodes

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to increase or apply similar voltages to the electrodes or to combine these two methods.

If voltages that are similar to one another are applied to the electrodes, it is necessary to apply that to the last acceleration electrode Apply a high voltage of over 10 kV to the adjacent focusing electrode. However, it is not possible to apply such a high voltage across a terminal pin at the end of the neck portion of the picture tube is arranged, because arcing can occur between the connection pin and the other connection pins, by means of which the required voltages are applied to other electrodes of the electron gun, e.g. heating electrodes will. It is possible to apply the aforementioned high voltage via a further button, which is located on the funnel section of the picture tube, but it complicates the assembly work and increases the manufacturing cost considerably.

In picture tubes of the type available under the legally protected name "Trinitron", three electron beams are used converged by a single electron lens, each electron beam passing through the central part of a single one Large diameter electron lens is passed. The three focused electron beams are deflected in such a way that that they each strike the same point of a grid provided with openings, which is arranged in front of the screen is; four convergence electrodes, which are arranged at the upper end of the electron gun, are used for this purpose and delimit three passages for the different electron beams. On two inner electrodes of this convergence electrode arrangement the same voltage is applied in each case, and this voltage corresponds to the anode voltage. To the each of the two outer electrodes of this arrangement becomes one

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Voltage applied, which is 0.4 - 1.5 kV lower than the anode voltage, so that the electron beams, which pass through the convergence electrode arrangement, are deflected in a lateral direction relative to the central beam.

With older cathode ray tubes, the relevant voltages were each over a further, the funnel section the button adjacent to the tube and via an electrically shielded cable connected to the button and the outer Electrodes was connected.

Recently, a coaxially arranged anode button has been used, with two electrically isolated from each other Electrodes of cylindrical shape belong to an anode voltage across an outer electrode and a convergence voltage via an inner electrode as well as an electrically shielded cable that feeds the inner electrode connects to the convergence electrodes. It is true that this is not the case when using such an equiaxed anode button required to provide two buttons on the funnel portion of the picture tube, but it still proves difficult and time consuming, the inner electrode of the anode button and the outer convergence electrodes using the electric shielded cable.

For the prior art, see Japanese Patent Publication 40987/72 and U.S. Patents 3,514,66? and 3,932,786.

The invention is based on the object of an electron centrifuge which is improved in comparison with the prior art mentioned for cathode ray tubes to create, especially one in which the desired voltages with the help a simple arrangement can be applied to the electrodes.

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According to the invention, this object is achieved by creating a Solved electron spinner, which includes several electrodes for focusing and accelerating an electron beam, the abs clinitts along an axis of the neck of a cathode ray tube are arranged. There is also a resistor, which appears as a zigzag pattern on a base formed of a ceramic material and disposed in the neck portion of a cathode ray tube such as a picture tube is. A high voltage equal to the anode voltage is applied to one end of this resistor. The voltages desired for focusing the electron beams and / or causing them to converge become taps located between the ends of the resistor. At the other end of the resistance there is one significantly lower voltage applied.

Embodiments of the invention are explained in more detail below with reference to schematic drawings. It shows:

Fig. 1 is an oblique view of an embodiment of a Electron gun according to the invention;

Fig. 2 is an illustration of the connections between certain electrodes and a resistor;

3 shows an axial section of the electron centrifuge according to the invention, which is arranged with a sealing effect in the neck portion of a cathode ray tube;

4 shows the section IV-IV in FIG. 3;

5 shows an axial section of a further embodiment of an electron gun according to the invention, which is shown with sealing effect is incorporated in the neck portion of a cathode ray tube;

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6 shows the section VI-VI in FIG. 5; and

7 shows a horizontal axial section of a color television picture tube with an electron gun of the in Fig. 1 type shown, however, the resistance element shown in Fig. And 2, which is one of the forms important features of the invention, is not shown.

As a first embodiment of the invention, the following an electron slingshot with an electron lens that only works with a voltage is described, as is the case with can use a picture tube, which is available under the legally protected name "Trinitron".

The picture tube shown in Figs. 1, 2 and 7 has a Neck section 23 and a funnel section 30. Of the Funnel section 30 is closed by a screen P, in front of which a grid provided with openings is arranged is. In the neck section 23 there is arranged an electron gun 1 shown in FIG. 1, three of which are shown in FIG. 7 Cathodes KR, KG and KB belong, which are aligned with one another in a horizontal plane. These three cathodes are arranged behind a control grid G1, which is followed by two prefocusing grids G2 and G3. Beyond these bars the main focusing lens is arranged in the form of a grid G4. The grids G3, G4 and G5 are Acceleration grid, which convergence electrodes 8 and 9 and 11 and 12 are connected downstream. On his way to Screen P, the electron beam coming from the cathode KR passes through the associated openings of the grids G1 and G2, then to pass through the grids G3, G4 and G5, whereupon the electron beam finally passes the space between the plate-shaped electrodes 9 and 12 passed. The electron beam coming from the cathode KG runs in a straight line

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through the electron gun 1 in order to leave it again between the convergence electrodes 8 and 9 before he arrives at the apertured grid AG. The electron beam emanating from the cathode KB passes through the associated openings of the grids G1 and G2, and then through the grids G3, G4 and G5 to the convergence electrodes 8 and 11, from where it falls onto the grid AG.

The neck section 23 of the picture tube is at the transition point to the funnel section 30 of a deflection yoke DY enclosed.

The inner surface of the funnel section of the picture tube is provided with a conductive coating 24 made of carbon, which also extends over the inner surface of the neck portion 23 extends backwards to the vicinity of the convergence electrodes 8, 9, 11 and 12. According to Fig. 7, a high-voltage contact button protrudes 31 through the wall of the funnel section 30 to apply a high voltage Eb to the conductive carbon coating 24, the screen P and the apertured grid AG can be applied. According to FIG. 1, in the free end 2 of the tube shaft connecting pins 4 installed.

Fig. 1 shows an electron gun according to the invention, the with a sealing effect is built into the neck portion of a picture tube, while Fig. 2 shows the connections between the associated electrodes and a resistor can be recognized. In Figs. 1 and 2 the electron gun is overall denoted by 1. The electron gun includes a shaft part 2 made of glass with an associated one Evacuation tube 3 and arranged on the shaft part 2 Terminal pins 4. These terminal pins are connected to various electrodes such as heating electrodes of the cathode ray tube

tied together. The electrodes or grids G1-G5, which are arranged coaxially, also belong to the electron gun are, each have a cylindrical shape and are supported by two supports 5 and 6 from. The convergence electrodes 8 and 9 are attached to a flange portion 10 of the fifth grid G5, and the convergence electrodes 11 and 12 are supported by a holding part 13 from the supports 5 and 6 made of glass. There are also connecting sections 14 formed on the flange portion 10. As explained below, the connecting sections are available 14 in contact with the carbon coating on the inner wall of the funnel section 30 of the picture tube, by means of which the desired high voltage Eb which is supplied to the screen P. , i.e. the anode voltage, is also applied to the fifth grid G5. Extends along the grids G1-G5 1 and 2, a resistor 15, which at one end by a support piece 16 made of metal and at the other end by a Connection line 22 is supported. Resistance 15 is formed as a printed resistance track 17 on a surface of a base made of an insulating material, e.g. a ceramic material. The printed resistance track is covered by a layer of glass. For example the resistor has a width of 10 mm, a length of 50 mm and a thickness of 1.5 mm. An end to the resistance path 17 and the fifth grid G5 are conductively connected to one another by the support piece 16, and between the A conductive connection is established by a line 19 to the fifth grid and the third grid G3. At a predetermined Point b, which is separated from one end of the resistance track 17 by a predetermined distance, is the resistance track 2 connected to the fourth grid G4 by a line 20; at another point a passing through is separated by a predetermined distance from one end of the resistance track, the resistance track is by a line 21 connected to the convergence electrodes 11 and 12. The other

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The end of the resistance track 17 is via a line 22 in electrical connection with a connector pin 4a. The convergence electrodes 11 and 12 are conductively connected to one another.

The electron gun described above is with a sealing effect in the neck portion 23 of a picture tube installed as shown in Figs. On the inner wall of the neck portion 23 and only shown in FIG Funnel section 30, a carbon coating 24 is arranged, with which the connecting pieces 14 are in contact. The carbon coating 24 is in conductive connection with a button 31 built into the funnel section of the picture tube and a high button on the outside of the picture tube Voltage of e.g. 30 kV is applied. In the case of the construction described, the amount fed in via the carbon coating 24 high voltage is applied across the connectors 14 to the convergence electrodes 8, 9 and the fifth grid G5, and the same voltage is applied to the third grid G3 via the connecting line 19 and one end of the resistance track 17 and the support piece 16 is supplied. Thus, the convergence electrodes 8, 9 and the grids G3, G5 are each the same Tension. In addition, the high voltage supplied through the anode button 31 is applied to the screen P.

The high voltage supplied to one end of the resistance track 17 is longitudinally at the tap a due to the voltage drop of the resistance path between the high-voltage end and the tap a is divided, and the voltage thus obtained becomes the Convergence electrodes 11 and 12 are supplied via line 21. In addition, the high voltage is divided by the tap b, so that one due to the voltage drop between the high voltage side End and the tap b receives a voltage which is lower than the anode voltage and which is above the line 20 is fed to the fourth grid G4. The line

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lines 21 and 20 are equipped with cable lugs or the like. to attach provided on the taps a and ti. Thus, the voltage applied to the convergence electrodes 11 and 12 is slightly lower as the voltage applied to the converging electrodes 8 and 9, and the voltage applied to the fourth grid G4 is a little lower. The other end of the resistance track 17 is connected to the shaft 2 through the line 22 built-in pin 4a connected, which is grounded via a variable resistor 25. The rheostat 25 is used for fine adjustment of the voltage applied to the convergence electrodes 11, 12 and the fourth grid C4. The first grid 1 and the second grid G2, the voltages in question from the outside of the picture tube are associated with them Terminal pins 4 supplied. Further connection pins are used to supply a current for the cathode heating device. In this way, predetermined voltages are fed to the various electrodes, which with the help of the taps of the resistor 15 can be derived from the anode voltage supplied via the connecting parts 14.

The resistance track 17 is produced, for example, in such a way that a mixture of a binder, glass powder and a Resistance material, e.g. a metal oxide powder, on a support in the form of a thin plate made of ceramic material is imprinted and burned in. For example, a paste containing 10 parts by weight of ruthenium oxide powder becomes 60 parts by weight Contains glass powder and 30 parts by weight of ethyl cellulose as a binder, shown in FIGS. 1 and 2 Printed in a zigzag fashion on a base made of ceramic material. The printed base is then burned, and finally a coating of glass is applied to the resistor track. The resistance value of the resistance track 17 is about 500 megohms between their ends. With the described decay to supply the desired voltages with the help of a resistor there is a risk of enlargement

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tion of the current loss, and therefore it is desirable to reduce the amperage to less than about 50 microamps. It is useful for connecting and supporting one end of the resistance track to which the high voltage is supplied is to use the support piece 16 made of metal which is welded to the fifth grid G5. The one with the connector pin 4a stiffened line 22 supports the resistance pad 15 and is also conductive to the low-voltage side Connected to the end of the resistance track. For this purpose, the support piece 16 and the line 22 with cable lugs or the like. Mistake.

In the embodiment described, the resistor pad 15 approximately the same length as the actual electron gun. Here it is possible to use a resistance track of sufficient length and to bring about a high voltage drop along the resistor. Furthermore, it is possible to make a voltage appear at the connection pin 4a for the low-voltage side end, which almost corresponds to the earth potential and does not exceed 2 kV. Thus, the convergence electrodes 11, 12 and the fourth grid G4 can be easily and safely regulated. Of course it is not necessary to provide the variable resistor 25 when the low-voltage end of the resistor track is directly grounded or is directly connected to a terminal at which there is a predetermined voltage. In the present case a voltage of 30 kV is applied to the convergence electrodes 8, 9, the fifth grid G5 and the third grid G3; A voltage of about 29 kV is applied to the convergence electrodes 11 and 12, and one is applied to the fourth grid G4 Voltage of 12 kV. The position of the taps a and b of the resistance track is chosen so that the desired Voltage drop results.

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The base 15 provided with the resistance track 17 is arranged according to FIG. 1 so that it extends along the electron gun 1 extends, and it is supported at one end by the fifth grid G 5, to which the high anodic voltage is applied while the other end is supported by the terminal pin 4a; the surface of the resistance track 17 is arranged so that it does not come into contact with the remaining electrodes. From the voltage divider terminals off, i.e. via the high-voltage end and the taps a and b, certain voltages are the Grids G5, G3, the convergence electrodes 11, 12 and the grid G4. Even if the voltage is on the pin 4a is regulated, there is thus no influencing of the electron beam TIodulationssystems to which one Cathode, the first grid G1 and the second grid G2 belong. According to FIGS. 1 and 4, the resistor 17 is on one side the electron centrifuge is arranged, on which there are no supports 5 and 6 made of glass. Therefore, it is it is not necessary to reduce the diameter of the electrodes or the diameter of the neck portion of the picture tube to enlarge. In the embodiment described here, the convergence voltage and the focus voltage are obtained by dividing the anode voltage with the aid of the resistor 15. Of course it would be too possible to obtain only the convergence voltage or only the focus voltage in this way. Will only the convergence voltage obtained by dividing the anode voltage, one of the connecting pins 4 can use the low convergence voltage supply from 0 to 5 kV.

With the picture tubes known up to now, with the exception of the aforementioned Trinitron picture tube, only the focusing voltage is used obtained by dividing the anode voltage. In Figures 5 and 5, another embodiment of the invention is for use shown for a picture tube that is not compatible with the

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1 described convergence electrodes 8, 9 »11 and 12 is provided. In the embodiment of FIGS. 5 and 6 is the electron gun designed as a so-called in-line electron gun for three electron beams, with only one single high voltage is operated, each grid electrode has a somewhat flattened shape, and each grid electrode Sir the three electron beams are each formed contiguously. In Figs. 5 and 6, parts shown in 1 and 2 correspond to parts shown, each denoted by the same reference numerals.

The base 15 provided with the resistance track 17 is arranged on one of the supports 5 and 6, which carry the grid electrodes G1-G6, each one slightly flattened Have shape. The sixth grid G6 is provided with a connector 14 which is in contact with a Carbon coating 24 on the inside of the neck portion 23 of the picture tube stands. The sixth grid G6 is through a line 26 to the fourth grid G4 and through another Line 27 is connected to one end of the resistance track 17.

A voltage applied to the resistance track 17 is divided with the aid of a tap a, and the one tapped there Voltage \ drd fed to the fifth grid G5 via a line 28, which is connected by a line 29 to the third grid G3. The grids G1 and G2 have associated pins 4 connected. Thus, the same high voltage of, for example, 30 kV becomes corresponding to the sixth and fourth grids The anode voltage is supplied, while a lower voltage is applied to the fifth grid G5 and the third grid G3 of e.g. 12 kV is applied. Optionally, the third grid G3 is separated from the fifth grid G5 and with a Connected other point along the resistance track 17, so that it is supplied with a voltage that differs from that of the fifth Grid G5 supplied differs.

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6 is in the second embodiment of the invention the resistance pad 15 is placed on the support 5 because the electrodes have a flattened shape. If necessary, the resistance pad could also be used in the manner described in relation to the first exemplary embodiment be supported, i.e. supported with the help of lines 27 and 22. It is also possible to use the base 15 to be connected by fusing with the support 5. One could assume that a direct printing of the resistance track on the support 5 made of glass with subsequent Burn-in leads to a simplification of the construction, but difficulties arise from the fact that the resistance value of the resistance track may change when heat treatment is applied to the supports 5 and 6 made of glass to soften so that the grid electrodes can be connected to them; here can there is a change in the form of support. In view of this, the one provided with the resistance track is therefore Base made of ceramic material connected by fusing to the support 5 after it has softened or the backing is previously connected to the support on its back.

It is also possible to connect the base 15 made of ceramic material to the support 5 made of glass after the grid electrodes have been connected to it. In this case a type of glass can be used to make the connection with a low melting temperature or a ceramic material of the Flit-type, e.g. the material which is below the legal protected name "Sumiseramu" by the Japanese company Sumitomo Kagaku Corporation will. In addition to the ruthenium oxide already mentioned, the materials suitable for the resistance track 17 also include oxides of the NiSiO type, oxides of the CrSiO type, nickel-chromium alloys, Copper-manganese alloys, metallic chromium, etc. These materials can be made into thin films with the help of spraying processes are processed.

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It is generally quite difficult to embed the anode button 31 in the funnel section 30 of the picture tube, and this operation is usually carried out by the manufacturer of the glass envelope.

With the Trinitron picture tube, the convergence voltage is almost the same as the anode voltage, so it is not that dangerous is to supply these voltages via coaxially arranged buttons, but it is dangerous to use the high focus voltage of e.g. 12 kV and the anode voltage via coaxial buttons, as there is a considerable risk of There is an occurrence of arcing. Therefore, the funnel portion of the picture tube has to be provided with two buttons. However, this leads to a serious new problem that, for example, it is necessary to electrically connect two to each other to provide separate inner carbon coatings and intricate interconnection cables for the buttons.

According to the invention, it is sufficient to provide only one anode button, and no special construction, such as an equiaxed button, is required. Besides, it is no longer necessary to connect the anode button to the convergence electrodes with a cable. Thus there is a simplified structure of the picture tube. If you put the length of the resistor essentially equal to the length of the electron gun selects, as is the case in the exemplary embodiments described, the result is a simplification of the Supporting structure and assembly work, and it is possible to accommodate a resistor that has such a high resistance value has that the desired voltage drop can be achieved.

With larger picture tubes, a correspondingly higher anode voltage is required, and the electron gun must be lengthened accordingly. According to the invention, one can give the resistive track, the required greater length, so that a larger voltage drop corresponding to the increase of the anode voltage ore ^ 3 £ | ^ ₉ g ₈

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Claims (23)

EXPECTATIONS Color picture tube with an evacuated tube piston, it has a funnel section and a neck section, a screen, a grille arranged in the outer end of the funnel section and provided with openings, an anode in the form of an electrically conductive coating on the inner surface of the funnel section and the inner surface a part of the neck section adjacent to the funnel section as well as with an electron gun arranged in the neck section, to which several electrodes belong, which are aligned along the axis of the neck portion are, with at least three electrodes forming main focusing electrodes, characterized in that, that a resistor is present, which includes a base (15) made of a ceramic material on which a resistance track (17) is located that the base is arranged so that it is along the electrodes (G1 - G6) extends that the resistance track has a high-voltage end, a low-voltage end and one between Tap (a) located at these ends has that the high-voltage end of the resistance track with the conductive Coating (24) is connected to the inner surface of the picture tube that at the tap a medium voltage for a Main electrode (G5) is tapped, which is lower than 809829/0998 ORIGINAL INSPECTED the tension at the high-voltage end of the resistor track, and that the low-voltage end of the resistor track with a connector (4a) at one end of the neck portion (23) is connected, which is supplied with a relatively low voltage, in order to discharge electrical discharges at other terminals to prevent that is arranged at the high-voltage end of the resistance track in the area of the neck section are. 2. Color picture tube with an evacuated tube piston, to which a funnel section and a neck section belong, a screen, an apertured grille arranged in the outer end of the funnel section, an anode in the form of an electrically conductive coating on the inner surface of the funnel section and the inner surface a part of the neck section adjacent to the funnel section and with one arranged in the neck section Electron slingshot to which an electron beam source is used Generating an electron beam propagating along the axis of the tube and several along the axis of the shark section aligned grid electrodes, at least three of these electrodes a first, a second and a third grid form, which come into effect as main focusing electrodes and serve to the To accelerate and focus electron beam, characterized in that a resistor is present, to which a base (15) belongs, on which there is a resistance track (17) that the base is extends along the various electrodes (G1-G6) and is enclosed in the neck portion (23) of the tube, that the resistance track has a first end, a second end and a tap arranged between these ends (a) comprises that the third grid (G6) and the first end of the resistance track is supplied with a high voltage which equal to the anode applied to the screen (P) of the tube Ö09829 / 099Ö voltage is that the second grid (G5) is supplied with a voltage which is lower than the anode voltage, and which is tapped at the tap of the resistor track that the first grid (G4) is supplied with a voltage that is higher than that at voltage applied to the second grid, and that the second end of the resistance track is connected to a terminal pin (4a) which is arranged at one end of the neck portion and to which a low voltage is applied to prevent electrical discharges from occurring between other terminal pins disposed at said one end of the neck portion. 3. Color picture tube according to claim 2, characterized in that the electrodes (G1-G6) of supports (5, 6) Glass extending on either side of the electrodes parallel to the axis of the neck portion (23) of the tube. 4. color picture tube according to claim 3 »characterized in that the resistor (17) in the electron gun on one Side of the electrodes is arranged on which there are no supports (5 »6) made of glass (Fig. 4). 5. color picture tube according to claim 2, characterized in that that the second end of the resistance track (17) of the electron gun is conductively connected to the connecting pin (4a) and is supported by this, and that the first end of the resistance track is conductively connected to the third electrode (G6) and is supported by them. 6. Color picture tube with an evacuated tube piston which has a funnel section and a neck section, a screen and an apertured grid in the outer end of the funnel section, an anode in the form an electrically conductive coating on the inner surface of the funnel section and the inner surface of a funnel end 809829/0996 cut adjacent part of the neck portion and an electron gun disposed in the neck portion and serves to generate three electron beams propagating in a common plane that pass through a single electron lens are accelerated and focused, with at least a first electrode, a second electrode and a third electrode aligned in that order along the path of one of the electron beams and form the electron lens, and two inner and two outer plate-shaped electrodes along the beam path are arranged near the third electrode to delimit three slots from the three electron strays are traversed to cause a deflection of the electron beams, characterized in that there is a resistor to which a base (15) belongs, on which there is a resistor track (17) that the resistor extends along the electrodes and in a neck portion (23) of the piston of the picture tube is included that the resistance track has a first end second end and a tap located between these ends (a) that to the third electrode (g6), the two plate-shaped inner electrodes (8, 9) and the first end of the resistance track applied a high voltage which is equal to the anode voltage applied to the screen (P) of the tube that to the plate-shaped outer Electrodes (11, 12) a lower voltage lying below the anode voltage is applied to the tap the resistance track is tapped, and that the second End of the resistance track with one at one end of the neck portion (23) of the tube is connected to the terminal pin, to which a low voltage is applied, to prevent the occurrence to prevent electrical discharges between other connecting pins located at said end of the neck portion are. 809829/0998 7. color picture tube according to claim 6, characterized in that the electrodes of the electron gun together of Supports (5, 6) are carried, which are arranged on both sides of the electrodes and are parallel to the axis of the neck portion (23) of the tube. 8. color picture tube according to claim 6, characterized in that the resistance of the electron gun arranged so is that it extends parallel to said plane and is separated from that plane by a distance. 9. color picture tube according to claim 6, characterized in that the first electrode (G3) and the third electrode (G5) the same voltage is applied to the electron gun, that this voltage is equal to the anode voltage, and that the second electrode (G4) is supplied with a voltage which is lower than the anode voltage. 10. Color picture tube according to claim 9, characterized in that the voltage applied to the second electrode (G5) of the electron gun is supplied, is tapped at a tap (a), with which the resistance between his Ends is provided. 11. color picture tube according to claim 6, characterized in that the resistance of the electron gun through the third Electrode (G5) and the connector pin (4a) is supported. 12. Color picture tube according to claim 6, characterized in that the connecting pin (4a) and the third electrode (G5) the electron gun are provided with claws for attaching the resistor. 13. color picture tube according to claim 2, characterized in that a pad to the resistance of the electron gun §09829 / 0998 (15) made of a ceramic material, on one surface of which a resistance material (17) in the form of a layer is arranged so that a large voltage drop is brought about between the ends of the resistor. 14. color picture tube according to claim 6, characterized in that a pad to the resistance of the electron gun (15) is made of a ceramic material on which a resistive material (17) is arranged in the form of a layer so that that a large voltage drop is brought about between the ends of the resistor. 15. TV picture tube with a glass bulb that has a neck portion and a funnel section, wherein a screen is arranged in the funnel section on which an electron beam generated in the neck portion is incident, and an electron gun enclosed in the neck portion of the glass envelope to which a plurality of electrodes are attached for focusing, accelerating and deflecting an electron beam generated by a cathode, the electrodes aligned along the axis of the neck portion are, characterized in that there is a resistor to which an insulating pad (15) belongs, on which there is a resistance track (17) that the resistor is arranged so that it is extends along the electrodes that the resistor is included in the neck portion (23) of the tube that the Resistor has a first end and a second end that the same voltage is applied to the first end as that Screen (P) that the second end of the resistor is slidably connected to a pin on which a voltage which is fed at one end of the neck portion is through which the second end of the resistor is connected to the outside of the glass bulb that a desired voltage for the electrodes one between the 809829/0998 tap located at both ends of the resistance track (a) is taken out that a voltage applied to the two ends of the resistance track corresponding to the resistance the resistance path is shared between the tap and the first end, and that of the connector pin applied voltage is sufficiently low to allow electrical discharges to occur between electrodes and the connecting pin to prevent. 16. TV picture tube near claim 15 »characterized in that that the first end of the resistance track (17) is conductively connected to a last acceleration electrode (G5) and supported by it, the same voltage being applied to this electrode as to the screen (P). 17. TV picture tube according to claim 16, characterized in that the second end of the resistance track (17) is conductive is connected to and supported by a pin (4a). 13. TV picture tube according to claim 17, characterized in that that the last acceleration electrode (G5) and the connecting pin (4a) are provided with metal claws which can be attached to the base (15) of the resistance track (17). 19. television picture tube according to claim 16, characterized in that three electron beams the focusing electrodes (G3 » G4, G5) run through centrally and through two plate-shaped inner electrodes (8, 9) and two plate-shaped outer electrodes Electrodes (11, 12) are deflected so that they come to the same point on a mask (AG) that before Screen (P) is arranged that the anode voltage is fed to the two inner electrodes, and that the two the external electrodes are supplied with a voltage that is lower 809829/0998 is than the anode voltage, and which is tapped at the tap (a) between the ends of the resistor. 20. TV picture tube according to claim 16, characterized in that the electrodes are jointly supported by glass rods (5, 6) are supported, which are arranged on both sides of the electrodes and are parallel to the axis of the neck portion (23) extend the tube. 21. TV picture tube according to claim 20, characterized in that that the resistor is arranged on that side of the electrodes on which there are no glass rods (5, 6) to support the electrodes are located (Fig. 4). 22. TV picture tube according to claim 16, characterized in that the resistor between its ends is a Has a resistance value sufficient to produce a large Cause voltage drop. 23. TV picture tube according to claim 16, characterized in that three electron beams (BR, BG, BB) are generated that propagate in a common imaginary plane, and that the resistance is essentially parallel is arranged on this plane and at a distance from it. 809829/0998