NL8401824A - TELEVISION ROOM TUBE. - Google Patents

Description

#> PHN 11.055 1 N.V. Philips * Incandescent light factories in Eindhoven.

"Television Canary Tube"

The invention relates to a television camera tube containing in an evacuated envelope a diode electron gun for generating an electron beam, comprising successively a cathode centered along an axis and having an emitting surface extending substantially perpendicular to this axis, an anode provided of a flat portion extending substantially perpendicularly to the axis just in the center, a portion extending in the direction of the cathode, the inner and outer walls of which converge towards the axis in the direction of the cathode, the outer wall of which merges into a head case parallel to the emissive surface top surface provided with a central opening.

Such a television camera tube is known from U.S. Patent 4,376,907 (PHN 9526) which can be considered to be incorporated herein.

Such a television camera tube further contains a target, for instance consisting of a signal layer with a photoconductive layer thereon, for recording the information of the image to be recorded. Between this target and the diode electron gun is a focusing lens for focusing the electron beam on the target and a 2Q aperture for limiting the electron beam.

In German Patent Application 29 42 063 laid open to public inspection, a similar television camera tube is described with a diode electron gun. The part of the anode extending in the direction of the cathode has an outer wall converging towards the axis in the direction of the cathode. The inner wall of this part and the rest of the anode is tubular and extends coaxially about the axis. A plate is fastened against the anode on the side remote from the cathode with a second gold diaphragm plate with a beam-limiting aperture on the catholic side. The distance from the top surface to this plate 3Q is, according to the figure shown in this patent application, about 1.5 times the distance from the emitting surface to the top surface.

Such television camera tubes as described above are generally known and are also referred to as vidicon. The 3401824 ΡΗΝ 11,055 2

Pi, -¾ operation of a vidicon is as follows. An electron beam of sufficient current strength, under the influence of the deflection fields, scans the free surface of the photoconductive layer of the target according to a given grid and points this surface pointwise to the potential of the cathode, which is called zero volt. Between two successive scans, the potential of each point of the free surface of the photoconductive layer increases under the influence of a positive potential applied to the signal layer and under the influence of photoconductivity generated in the photoconductive layer by the projected optical image . Each point, or exactly every elementary surface element, of the photoconductive layer together with the underlying signal layer forms a capacitor. The charge of this capacitor is periodically replenished by the scanning electron beam, which requires more charge as more light falls on the point in question. As a function of time, the current which flows through the connection of the signal layer contains the information of the projected image. The current of the electron beam must be large enough to provide sufficient charge to elementary capacitors which are strongly discharged as a result of high luminous intensity. Once the free surface of the photosensitive layer has been reduced to zero volts at some point, the electrons from the electron beam cannot further reach that point.

Their speed becomes zero and then they are accelerated in reverse and form the so-called return beam. This return beam is also affected by the deflection fields and scans the surface of the diaphragm facing the photoconductive layer. A portion of the secondary electrons generated on the diaphragm has almost the same kinetic energy as the electrons of the return beam and forms a secondary beam which, together with the original (primary) electron beam, scans the photoconductive layer at a different location than the primary electron beam, because the secondary beam passes through the deflection fields elsewhere. This creates a disturbing signal that is visible in the image to be displayed.

In order to largely prevent the adverse effect of the return beam, German Patent Application 35 2230529 (PHN 5726) which discloses the surface of the diaphragm facing the photoconductive layer, provided that this is not in the immediate vicinity of the axis of the tube located at an acute angle to the direction of this axis. This is preferably accomplished by giving the 1401824 PHN 11.055 3 diaphragm the shape of a truncated cone which extends in the direction of the target and the aperture is provided in the top face. Therefore, the secondary beam has a principal direction which is not directed towards the target, because a very large part of the generated secondary electrons has a direction which is related in the same way to the direction of the primary (incident) electrons and to the normal on the surface of the diaphragm if this is the case with reflection of light rays (the angle of incidence is equal to the angle of reflection).

In German published patent application 24 34 139 another solution is given. It is proposed to provide a flat diaphragm on the target side with a layer of a material having a low secondary emission coefficient. Chromium is particularly suitable, on which an ozyde skin soon forms in air.

As is known, from German patent 587,386, chromium oxide is a very good suppressor of secondary emissions.

However, in houses with flat, convex or conical diaphragms where the above measures have been taken, the following problem arises. At small deflection angles of the primary electron beam, a false signal due to secondary electrons still occurs in the recorded image.

It is therefore an object of the invention to indicate a television room in which these interfering signals are minimized.

A television comb tube of the type described in the first paragraph is for this purpose characterized according to the invention in that a flat electrode electrically connected to the anode is arranged at a distance d from the surface on the side of the anode remote from the cathode, wherein d is located between 4 and 25 times the distance from the surface of the surface to the emissive surface, which flat electrode is provided with a central opening which has a diameter which is substantially equal to the diameter of the electron beam at the location of the electrode.

The origin of the secondary electrons that give rise to the interference signal was initially unclear. The application of the invention provides the insight that at small deflection angles of the electron beam, a part of the return beam still falls through the aperture opening. For tubes with a diode electron gun, this part of the return beam is focused on the anode through the focusing lens 8401324 CS. PHN 11.055 4 generates secondary electrons that can again reach the target and give rise to interference signals there. During the scanning of the target by the electron beam, the anode is also scanned by the return beam focused thereon.

Because the central portion of the anode on the side facing away from the cathode in the known starting diode guns has an axis converging wall as described in U.S. Patent 4,376,907 or, as in German Patent Application 29 42 063 described, consists of two plates at a different location along the axis and two materials, and the return beam is focused on this anode, due to this irregular design and / or differences in material, rapid changes in the number of secondary electrons generated, thereby promoting the perceptibility of the interference signal.

By using an entirely flat electrode at a sufficient distance d from the flat top part of the anode, the return beam falls on this electrode. Because this return beam is less focused at the location of this electrode and the electrode is flat, the number of generated secondary electrons will vary relatively slowly, so that the signal caused thereby becomes visible to a lesser extent.

The opening in the flat electrode has a diameter such that the passage of the useful part of the electron beam is not obstructed. This diameter is preferably equal to the diameter of the electron beam at the location of the flat electrode or at most 25% larger.

If the flat electrode is attached to the anode by means of a metal cup-shaped spacer widening in the direction of the flat electrode, the flat electrode can be easily built into drawn dicecon guns. Such a diode electron gun is described in European Patent No. 0048510 (PHN 9840), which can be considered to be incorporated herein.

If the flat electrode at least on the side remote from the cathode consists of a material having a secondary emission coefficient of less than 1, the total amount of secondary electrons generated at the anode is still reduced.

8401824 W £ * ί EHN 11,055 5

The invention is now further explained by way of example with reference to a drawing, in which: figure 1 shows a cathode radial tube according to the invention in a longitudinal section, figure 2 a part of figure 1 in view and figure 3 a part of figure 1 in section shows »

Figure 1 shows a longitudinal section of a television camera tube according to the invention. This tube contains a cylindrical glass envelope 1, which has a stepped shape obtained by suctioning a heat-made glass tube onto a stepped doom.

This tube is closed on one side by a window 2, on which the photosensitive target 3 is mounted on the inside. The window 2 rests on edge 4, which is parallel to the step surfaces 5, 6 and 7 against which a mesh electrode 8, a diaphragm 9 and an anode 10 rest, respectively. In this manner, the said parts are accurately positioned relative to each other. Wall electrodes are provided on the inner wall of the cylindrical envelope in the usual manner, which are not shown in this figure. A cathode carrier 11 is mounted against a first electrode, the anode 10. The glass envelope 1 is closed on the opposite side of the window with a cap 12, which is attached to the tube by means of an enamel 13. Connecting strips 14 extend from the cathode carrier 11, which spring through the enamel seam and also form the connections for the anode, the cathode and the cathode glow current. The target 25 3 usually consists of a photoconductive layer which is applied to a transparent signal plate. However, the target is also possible. contain a heat-sensitive layer. The return beam 100 returning from the target (indicated by a dashed line with an arrow) passes through small aperture angles of the primary electron beam through aperture 101 in the diaphragm 30 because the tapered anode (see FIGS. 2 and 3) of a flat plate electrode 102 having a central aperture 103, because of this flatness and because the return electron beam is not focused there, no rapid changes in the amount of secondary electrons generated will occur.

Figure 2 shows a view of part of Figure 1. On the stair surface 7, which forms a part of the inner wall of the envelope that is perpendicular to the axis 20 of the envelope, the anode 10 lies, which of a funnel-shaped opening 21 is provided. This anode is described in detail in 8401824 PHN 11,055 6 in U.S. Patent 4,376,907. The cathode carrier 11 is mounted against the anode 10. This support contains a first plate-shaped metal part 22, which makes electrical contact with the anode.

The second plate-shaped metal part 24 and the third plate-shaped metal part 25, which are located in one plane, are secured against this first plate-shaped part by means of an electrically insulating soldering glass 23. These two parts form the connections for the cathode filament 29 via the contact springs 26, the rods 27 and the metal vanes 28. A fourth plate-shaped metal part 30 is again attached to these two plate-shaped parts 24 and 25 with an electrically insulating solder glass 23. . This fourth plate-shaped part is provided with strips 31 which extend parallel to the shaft 20 in the tube. A metal intermediate plate 32 is attached to these strips from which the cathode shaft 33, provided with the emissive surface 37, is suspended by means of straps 34. The metal intermediate plate is provided with a central opening in which a heat reflection screen 35 is arranged coaxially around the cathode shaft 33. This cathode shaft disposed in a heat reflection screen is the subject of Netherlands Patent Application 8002343 (PHN 9733) laid open to public inspection, which can be considered to be incorporated herein. Terminal strips 36 extend through 2Q the four plate-shaped parts, which together form the cathode carrier 11, which are fed via the enamel 13 to the outside of the tube and the electrical connections for the anode, the cathode and the cathode glow form current. The rods 27 are arranged in the intermediate plate 32 by means of a soldering glass 23. The anode 25 further includes a metal cup spacer 104 extending in the direction of the flat electrode 102. The electrode 102 provided with aperture 103 is coated with gold on the side facing away from the cathode to provide secondary emission and surface charge as much possible to prevent.

Figure 3 shows a cross section of the part shown in Figure 2.

The anode 10 is provided with a flat portion 105 extending perpendicular to the axis 20 with in the center a portion 106 extending in the direction of the cathode, the inner and outer walls 107, 108 of which converge towards the axis 20 in the direction of the cathode. . The outer wall 108 35 merges into the top surface 109 which is provided with a central opening 110. At a distance d from the top surface 109 on the side of the anode 10 facing away from the cathode, a flat electrode 102 electrically connected to the anode is provided. The distance d is between 8401824 EHN 11.055 7 4 and 25 times the distance from the top surface 109 to the emissive surface 37 so that the return beam is not focused on electrode 102. The flat electrode 102 has a central opening 103 which has a diameter approximately equal to the diameter of the electron beam at the electrode 102.

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Claims (4)

1. A television camera tube comprising, in an evacuated casing, a diode electron gun for generating an electron beam, comprising successively a cathode centered along an axis and having an emitting surface extending substantially perpendicular to this axis, an anode provided with an substantially flat portion extending perpendicular to the axis with in the center a portion extending in the direction of the cathode, the inner and outer walls of which converge towards the axis in the direction of the cathode, which outer wall merges into a substantially emissive surface parallel to top surface provided with a central opening, characterized in that a flat electrode electrically connected to the anode is arranged at a distance d from the top surface on the side of the anode remote from the cathode, d being located between 4 and 25 times the distance from the top surface to the emitting surface, which flat electrode is provided with a central opening which has a diameter which is substantially equal to the diameter of the electron beam at the location of the electrode. Television camera set according to claim 1, characterized in that the diameter of the opening in the flat electrode is substantially equal to the diameter of the electron beam at the location of the flat electrode or is at most 25% larger. A television camera tube according to claim 1 or 2, characterized in that the flat electrode is attached to the anode by means of a metal spacer element widening in the direction of the flat electrode. Television camera tube according to any one of the preceding claims, characterized in that the flat electrode at least on the side remote from the cathode consists of a material which has a secondary emission coefficient smaller than 1.30 35 8401824