FR2579823A1 - Electron gun and television tube using such a gun - Google Patents

Abstract

The invention affords a solution in the construction of the gun to the problem of cathode glow which appears fleetingly when turning off the supplies to the tube. In order to effect this solution, the ratio d3/d4 is reduced without in any way affecting the quality of the electrostatic lens.

Description

ELECTRON CANON AND TELEVISION TUBE
USING SUCH A CANON
The present invention relates to an electron gun and a television tube using such a gun.

 In the prior art, it has been noted that certain types of television tubes have a particular defect. When the power is turned off, the screen image disappears. But a violent glow then of decreasing intensity lights up in the center of the screen. The phenomenon is known as a cathode glow and can have drawbacks about the comfort of the tube user.

 An effective solution is already known which consists in having a diode which makes it possible to discharge the high voltage to ground when the supply is cut. But it requires an additional component to correct a defect specific to the tube rather than to the electronic circuits which surround it in a receiver.

 The invention provides a remedy to these drawbacks of the prior art. Indeed, it relates to an electric cannon comprising at least one thermo-emissive cathode emitting an electron beam and successively along the beam at least a first grid and a second grid brought to a potential greater than that of the first grid, each grid being pierced with at least one hole aligned with an electron beam, characterized in that the ratio of the diameter of the hole of the first grid to that of the hole of the second grid is less than 1, in order to limit the penetration of the high equipotentials behind the hole in the first grid.

 It is based on the following analysis of the phenomenon. When the power is turned off, the thermo-emissive cathode is hot.

As it is grounded through a high resistance, a cathode voltage appears. The cathode being hot, electrons are emitted according to a density law varying with the temperature. However, the cathode voltage which appears is first of all a blocking voltage relative to the residual voltages in the various grids connected almost directly to ground. As long as this voltage does not drop below a given threshold, no fault appears. But the temperature decreasing, this tension becomes lower than the blocking. The acceleration voltage residues are then applied to thermally emitted electrons and the cathode image in the form of a glow will last on the screen as long as the density of emitted electrons exceeds a certain threshold, or the accelerating voltages become insufficient. In the most unfavorable cases, the phenomenon lasts about ten seconds. However, it is avoided with guns whose grid at very high accelerating voltage is sufficiently far from the cathode. However, in other types of guns and since the phenomenon is fleeting, it is necessary to limit the effect of the high voltage grid that is too close.

 On the other hand, certain types of guns have grids pierced with holes of diameters calculated to obtain an image of a cathode in operation (we also say: "a lit point") of suitable shapes and energy, which are mounted in manufacturing on needles that align them. These needles have shoulders on which the grids abut, the hole diameters of which are rather decreasing when they are closer to the cathode. It is thus only possible to vary the dimensions of the holes in certain proportions which still allow mounting on manufacturing needles.

In the drawing, we have represented
- Figure 1: a section of a cannon which creates the cathode image problem;
- Figures 2 and 3: a series of equipotential lines which show the effect of the means of the invention.

 A barrel conventionally comprises two distinct parts: - a part 1 which allows the formation of the electron beam torn from the cathode by thermal effect; - an accelerating and focusing part 2 which makes it possible to constitute a suitable electron beam.

In the embodiment, the barrel mainly comprises a cathode K and two electrodes G1 and G2 flat in the form of discs drilled along the axis of the beam. In the case of a three-beam cannon, for a three-color tube, each electrode or grid consists of a plate pierced with three holes arranged along the axes of the desired beams. Part 2 has four G3 grids a
G6 forming a main electrostatic lens consisting of a bipotential lens G5-G6 and a unipotential lens G3-G4-
G5. To this end, a medium voltage is applied to the common terminal 3 of the gates G3 and G5 and a very high voltage to the common terminal 4 of the gates G4 and G6. These voltages are for example 8 and 25 kvolts.

Of the four grids G3 to G ;, only the grid G4 is flat, the others being formed by cylinders. In particular, the grid
G3 is a closed cylinder pierced with at least two openings aligned on the axis of an electron beam. The outlet opening is of a dimension d3 common to all the openings which follow in the grids G4 to G6 and larger than the dimensions of the preceding grids which are decreasing. The dimension d3 is calculated, according to the prior art, so as to produce an optimal main electrostatic lens with regard to the formation of an image on the screen of the television tube. This dimension is limited in particular for a cannon with three beams in line, usually used in three-color tube, by the necessary bringing together of the three axes of the beams. This arrangement of the dimensions of the openings of the grids allows them to be threaded on a needle during the mounting process as is known from the prior art.

In this type of tube the distance d which separates the gate G4 at very high voltage from the cathode K is relatively small, for example of the order of 8 millimeters. Also, the influence of the vanishing voltages at the power cut is important.
The invention starts from the observation made during tests that the relative reduction in the ratio d3 / dss where d4 is the dimension of the opening of the gate G4 at high potential makes it possible to cancel the parasitic phenomenon of cathode glow.
In the preferred embodiment, the diameter d3 is reduced.

 In Figures 2 and 3, we have shown the form of equipotential lines in a first case (Figure 2) where the ratio d3 / d4 is equal to 1 and a second case (Figure 3) where the ratio d3 / d4 is lower to 1, by decreasing the diameter d3. In these figures, a partial and schematic half-section of the barrel of the type shown in FIG. 1 has been shown. The axis z represents the axis of the electron beam with its direction of propagation when the grids G1 to G6 are under voltage.

The place of the grids G1 to G5 and of the cathode K is indicated by the hatched drawings.

Line L1 in Figure 2 shows an equipotential line arc. It intersects the z axis at A. The z axis is cut by equipotential lines of increasing level as one moves away from the cathode. The point A is here behind the point O projection of the entry hole E of the grid G3. We note that according to such an equipotential line as soon as electrons appear in the interval
G2-E, they will be focused and accelerated along line L1.

 In FIG. 3, the equipotential line L2 of the same level intersects the axis z at B, in front of the point O. It can be seen that the influence of the high voltage of the gate G4 is therefore reduced by the reduction in the diameter d3. It has been found that a d3 / d4 ratio of 0.6875 makes it possible to obtain a good compromise between the quality of the image of cathode in image formation and reduction of the parasitic phenomenon of cathode glow when the power supplies turn off.

 However, the outlet hole of the grid G3 as shown in FIG. 1 has a cylindrical flange which advances by a depth p inside the cylinder G3. This flange can be obtained in the manufacture of G3 by extrusion. Its effect makes it possible to reduce the reduction in the ratio d3 / d4 necessary for the invention. In an exemplary embodiment for a compromise comparable to that obtained previously, a d3 / d4 ratio of 0.844 was produced.

 The invention achieves the desired result by limiting the influence of the high level equipotential lines in the beam forming area. In other technologies than that described above, such an effect can be achieved in particular by increasing the dimensions of the holes of the grids following the very high voltage grid.

 The invention also applies to the case where the grid G4 is thick, for example made in the form of a cylinder. Its proximity to the filament being unchanged, the problem and the solution of the invention remain.

Claims (4)

 1. Electric cannon comprising at least one thermoemissive cathode (K) emitting an electron beam and successively along (z) the beam at least a first grid (G3) and a second grid (G4) brought to a potential greater than that of the first grid, each grid being pierced with at least one hole aligned with an electron beam, characterized in that the ratio of the diameter (d3) of the hole of the first grid to that (d4) of the hole of the second grid is less than 1, in order to limit the penetration of the high equipotentials behind the hole in the first grid (G3).  2. Electric cannon, the first grid (G3) of which consists of a cylinder elongated along the electron beams and according to claim 1, characterized in that the diameter (d3) of the hole in the exit face of the first grid is reduced relative to the diameter of the hole in the second grid.  3. Electric cannon according to claim 2, characterized in that the reduced hole also comprises a cylindrical flange extending from a depth p towards the inside of the cylinder.  4. Television tube using a cannon according to one of the preceding claims to reduce the light effect of the cathode image on the screen when the chassis is cut.