DE1489156A1 - Method of manufacturing a secondary emission electrode for electron tubes - Google Patents

Description

Note: NVPl !. '. ⁱ :: s ^{£ 1} LAMP LAMP FACTORY

Act: PHB- 31 180
Registration dated: April 20, 1964 IARQ IRR

Dr. Expl.

N.V. Philips'Gloeilampenfabrieken, Eindhoven / Holland

"Method of making a secondary emission electrode for electron tubes "

The invention relates to a method for producing a secondary emission electrode for electron tubes, in particular for image converters and image intensifiers, from a body made of GIa ₈ or similar material with two parallel interfaces and mxt small passages which form a network of high density and connect the two surfaces with one another.

In such a secondary emission electrode, the number of Electrons enlarged on the way from one interface to the other as a result of secondary emission; they wander through it the passage of the electrode under the action of an electric Field between the two interfaces. These are covered with a conductive layer, between which an electrical Tension lies.

The secondary emission reinforcement comes about in the culverts. Relatively few electrons pass through unhindered the passages from one side of the body to the other.

PHB-31 180
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The remaining electrons not only have a forward direction, but also a sideways velocity component, whereby they hit the wall of the passages. «These walls are designed in such a way that two or more electrons are released be when an electron hits, so that as a result of the successive The electron density is considerably greater when it hits the ground will"

To ensure an even distribution of tension along the electron guns A sufficient amount of electrons must be maintained to maintain it are supplied from the voltage source, which the discharged Replace secondary electrons. On the other hand, the conductivity of the wall should not be so great that the material is heated » The body can consist of aue glass, the resistance of which is between

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TO and 10 Ohmtem, or the walls of the Durohläsee can, if the body is made of insulating material, be covered with a thin conductive layer, which is preferably made of consists of a material that can move at the usual electron speed a secondary weight factor exceeding the value 1 If necessary, such a substance can be applied separately to the inner surface of the passages.

Such a body that can be used as a secondary emission electrode hereinafter referred to as matrix. The production of a BOlohen matrix is not easy. The matrix is supposed to be final 3 to 10 cm in diameter and about 10 passages x of about 10 µm in diameter per square centimeter ii »have» the Thickness of the body can be 1 to 2.5 mm. The passages should be evenly distributed over the surface, either according to a certain pattern or in such a way that the density on the surface is almost the same everywhere. A smooth inner surface and a constant diameter of the passages in the longitudinal direction are important to avoid differences in the secondary emission performance the passages are avoided,

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The invention aims to provide a method for manufacturing to indicate a matrix that fulfills the requirements in a number equal to the desired number of passages in the body joined together in a gauge and heated together, whereby by contracting the gauge the walls of the tubes together are connected and the confluent material fills the gaps.

The use of tubes solves the problem in a simple way, • a sufficient number of passages in the difficult to work To attach the material of the matrix serving as the secondary electrode.

There are a few ways to achieve the desired composition, sox & hl heights of small diameter with the desired dimensions of the passages as well as Eöhrohen larger Diameter can be used. All tubes required can be grouped together, or a smaller one can be used Number to be put together in bundles and connected to each other. In the latter case, it is advantageous to have such a number in each case of tubes so that together they fill a polygon of such a shape that a number of such bundles are practical fit together without gaps.

Glass types are suitable as a material for production purposes Have insulating properties or have a specific electron conductivity. So-called soft glass, which has a low Melting temperature can be used as a coating for tubes made of a harder type of glass with a higher melting temperature. The production of tubes with a jacket-like coating is known per se. When melting together, that's easy fusible material establishes the connection between the tubes, without the inner shape of the tubes being changed by the heating,

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The inner Durohmeeser of the tubules can be heated for the production of the mutual connection sufficiently high temperatures can also be maintained undeformed in other ways. For this purpose, the auricles are provided with a core of some form. »They are easily fusible metals such as indium, Lead, zinc, tin and aluminum or chemically soluble metals such as copper, gold or tungsten can be used. It can also be a caged one Grass volume can be used as a core o.

Long, thin glass tubes in the form of a jacket can awe around a solid core can be made by using a thin metal wire drawn through a bath of liquid glass. Another method is to attach a glass plug to the end of the wire whereupon the glass is spread along the wire in a series of operations by means of drawing dies.

In a sequence of operations, the tubes can be made thinner and thinner. Becomes the original tube filled with metal, the melting point of which is lower than the glass transition temperature required for drawing, this remains the same Metal filling after sealing the pipe ends back as core until after the end of the work process.

The drawing of the separate tube ends after they have up to a diameter narrows, the number of times, for example, _e times, is larger than the finally required Durohmesser. A number of such tubes are then bundled together and connected together, and pulling is continued until the passages are of the desired size. A set of tubes grown on this catfish has a small cross-section compared to the size of the matrix, so that many more such sets have to be joined together. A round cross-section of the tube sets is less suitable for filling a cross-section, so that it is advantageous to combine a number of tubes to form a set, the cross-section of which

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forms a completely filled out vielok, taking care of that that this shape is maintained when pulling. Useful Polygons must have such a shape that many bundles can together form an uninterrupted whole; only the triangular ones square and hexagonal shapes are suitable.

The drawing shows some exemplary embodiments, the figures 1, 2, 3 and 4 show compositions of tube bundles and

Figures 5, 6, 7 and 8 illustrate the composition of a matrix.

A relatively small number of tubes with an outer diameter of e.g. about 6 mm forms a first bundle. A hexagon can consist of seven tubes according to FIG. 1 or from e.g. 19 Tubes can be assembled according to FIG. 2. With 7 tubes, a triangle according to FIG. 3 can be formed. Except for these regular ones For polygons, a diamond shape of e.g. 9 tubes according to Figure 4 is also suitable Tubes drawn while maintaining the shape shown. Sets of such structures are shown in FIGS. 5, 6, 7 and 8.

A glass tube can be sufficient to get the composite shape large diameter can be filled with separate tubes or with sets of tubes of a certain length to have. The tube is at both ends except for one opening closed, which is in communication with a vacuum line. During the heating process, air is pumped out of the pipe so that the wall warps inward when it softens and tightens the tubes tightly together, melting them together. It are then made by making cuts perpendicular or at an angle to the axial direction of the openings from that obtained after cooling Block cut off thin plates with a thickness of 1 to 2.5 mm. The core material is then removed.

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The use of such a matrix as a secondary emission electrode is explained on the basis of some figures from the drawing, Figure 9 shows the application and the required electrical Means illustrated and Figure 10 explains the arrangement of the electrode in an electron tube.

The body 1 with the passages 2 forms the secondary emission »- electrode and is arranged in the course of an electron beam, whose tracks 3 are indicated. On both sides, the body material made of glass is electrically conductive Layer coated, which leaves the passages 2 free. the Layer 4 is on the impact side of the electrons and the Layer 5 is on the opposite side, i.e. on the exit side} at a short distance from this see the Collecting screen 6 for the electrons. An electrical voltage between the conductive layers 4 and 5, which is generated by the voltage source 7, and an electrical voltage from a voltage source 8 between the layer 5 and the collecting screen 6 accelerate the electrons towards the screen.

For the sake of simplicity, the electron orbits are parallel to the Axes of the passages shown, but many orbits deviate somewhat from this alignment. As a result, the electrons touch of these tracks somewhere the wall of a passage. The electrons moving along the indicated paths also change their direction at the inputs of the passages when the electrical Field strength at the beginning of the passage is different from that in the present room, which creates the equipotential surfaces are curved in the entry plane. These electrons are then bent in the manner shown in the drawing. Along the Walls of the passages 2, the electrons are increased by secondary emission, and those emerging from the passages 2 Electron bundles hit the collecting screen 6.

This arrangement can be used for an electron tube shown in FIG 9 be suitable, consisting of a sheath 10 made of insulating material

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which includes a vented tree · The flat end walls 11 and 12 have on the inside a photoconductive cathode 13 and the electron collecting screen 6. In the tree between the two walls is the secondary emission electrode 1 arranged with the passages 2. An image of the object 15 is thrown onto the photocathode 13 by means of a lens 14. As a result of the exposure, the photocathode emits electrons, which pass through the secondary emission electrode and the collecting screen 6 ", which consists of a fluorescent layer which a visible image is obtained which corresponds to the image on the photocathode.

Claims

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Claims (1)

Patent claims 1.) Method of manufacturing a secondary emission electrode for electron tubes, especially for image converters and image intensifiers, which consists of a body made of glass or a similar material with two parallel interfaces and passages which form a network of great density and connect the two surfaces with one another, characterized in that that separate tubes in a number equal to the number of the desired passages in the body are assembled in a jig and heated together, whereby by contraction According to the doctrine, the walls of the tubules are connected to one another and the confluent material creates the spaces between them fills out. 2e) Method according to claim 1, characterized in that the Tubules with a jacket made of glass with a lower melting point than that of the material of the tubules. surround will, 3o) Method according to claim 1, characterized in that the tubes are provided with a metal core which is removed after manufacture. 4.) Process according to claims 1 and 3, characterized in that that the tubes are provided with a core of a metal whose melting point is lower than that of the material the tube is. 5.) Process according to claims 1 and 3, characterized in that that the tubes are obtained in the form of a coating adhering to a metal wire by inserting the metal wire through a Melt of a coating material is performed. - 9 - 909820/0478 H89156 6,) Vexfahren according to claims 1 to 5, characterized in that that a part of the required tubes are each put together in bundles and connected to one another, whereupon a number this bundle can be put together to form the body 7.) The method according to claim 6, characterized in that the one Part of the bundles comprising the required tubes have the same polygonal cross-sections with almost no space between them fit together » 8 ») Method according to claims 1 to 7» characterized in that that a teaching from a glass tube is used, the ends of which ä are closed and its closed tree evacuated will· 9.) Secondary emission electrode consisting of a set of tubes is made by a process according to one or more of claims 1 to 8 are made, which electrode is limited by two parallel surfaces that are covered with electrically conductive layers. 10.) Electron tube with a secondary emission electrode according to claim S ₉ which is arranged in a vented tree, in which opposite one side of the electrode a photolextending cathode and opposite the other side of the electrode an i Luminescent screen is arranged 909820/0478