DE1439585A1 - Electron beam imager - Google Patents

Description

iMüncheEl-Pullach, February 28, 1962

TEKTRONIX, IFC, 13 955 Southwest Millikan Way, Beaverton, Oregon, U.S.A.

Electron beam imager

i) The present invention relates generally to electron beam imaging devices and particularly relates to an improved piston structure for such imaging devices.

The bulb structure according to the invention can be used particularly advantageously for cathode ray tubes, as they are in one Cathode ray oscilloscope used. The detailed description the invention therefore makes reference to this field of application.

Briefly stated, the piston assembly of the present invention includes the following components; a piston with one out Body part made of ceramic material, one end of which is substantially in the form of a rectangle with a hollow cross-section has, with a face plate part, which is made of transparent or transparent glass in the form of an essentially flat, rectangular plate is made, the shape of which is adapted to this one end of the body portion and this by means of a

809806/0371

1 39585

Closure section is attached, which consists of a glass frit best ent, whose coefficient of thermal expansion is similar to that of the ceramic material and the translucent glass and whose softening temperature is below that of the ceramic "material and the translucent glass | one on the inner surface of the ceramic body portion of the Piston applied resistance coating made of a non-carbon containing ,, , heat-resistant material, the strength of which can change and the one graded resistance per unit area and is electrically connected to act as a post-deflection acceleration anode electrode acts; one on the inner surface of the flat faceplate portion The graduated scale is attached to the piston and is arranged in such a way that the graduation is illuminated by light can be, which by the peripheral edge of the faceplate section occurs.

Common cathode ray tubes have pistons made entirely of glass, the round or rectangular end faces of which Wear fluorescent screens. Cathode ray tubes with round faces need a lot of unnecessary in a cathode ray oscillator Place, · as the upper and lower parts of the round luminous screen rarely or never used to reproduce the observed electrical signal wave. It's difficult to get a rectangular one Manufacture of glass bulbs as the side walls tend to "tilt" during high temperature evacuation to deform inwards and because of the glass tensions at the corners with a small radius of curvature cracks. if hence the common glass bulbs with a rectangular faceplate are formed, the corners of the rectangular funnel

80 980 6/037 1

cut off ζμΓ reinforcement with a large wall thickness, whereby the usable surface of these front panels is also reduced. In addition, the molded glass front panels of the common cathode ray tubes are more curved than flat. As a result is an additional flat, outer reticle required that is in contact with the outer surface of the faceplate is arranged around a reticle illuminated at the edges to determine the relative dimensions of the waveform under observation. This curved front panel and its outer line division cause a distortion of the image of the waveforms "parallax." in the image of the reticle when viewed via a camera or directly by a human observer.

Common cathode ray tubes also come with a Resistance coating made of Aquadag or other carbonaceous material with a low oxidation temperature on the inner surface of the Body part of the bulb provided, which in some cases is connected so that it is only an extension of the second anode of the beam system acts or in other cases as an acceleration anode, which increases the speed of the electron beam after it has been deflected by the electrical signal to be examined became. So far, the post-acceleration anode has either been designed in the form of several, spaced apart, insulated coating sections of the same thickness, each of which has been placed at different potentials, or it has been designed as a single one helical coating of uniform thickness applied in order to generate an electrical potential gradient, the strength of which from the lighting beam system to the fluorescent screen of the Cathode ray tube increases. These common, spiral-shaped resistance coatings, divided into several parts, are

80 980 6/037 1

1439S85

.τ 4 -

however, do not provide a uniform acceleration of the electron beam "or do not create a uniform electric field within of a given cross-section of the tube, furthermore, the carbon material of these coatings oxidizes if it is during the with Heating associated evacuation process high! Temperatures is exposed, which are necessary for "an effective degassing" to the gases absorbed in the cathode ray tube to remove.

By the piston structure according to the present invention, the Disadvantages of the common cathode ray tubes discussed above to be overcome. By using a piston with a ceramic body part, a piston becomes more sufficient Strength created so that it can be made with a small, substantially uniform wall thickness and one end with a hollow ^ in cross section may have a rectangular shape, wherein with this end a translucent glass front panel in Shape of a flat plate with the same shape as the cross section sf surface of the body by means of a glass frit melt-in which are essentially the same Thermal expansion coefficients such as the ceramic material and the transparent glass and an essentially deeper one Softening temperature only than this ceramic material and that Can have clear glass, so the waste of space the usual glass tubes is avoided. The line scale can be illuminated directly on the inner surface on / ien edges Faceplate are attached so that the parallax of the line image and the distortion of the image of the waveform that occurs in common Tubing occurs, is eliminated. The cover for the Close-up acceleration anode can also be made from a non-carbon

80 98 06/0 371

containing heat-resistant material so that evacuation is possible at high temperatures, whereby the coating can be designed with a variable thickness, namely so that the thickness of the coating is closest to that of the front panel and the one that is furthest away from the front panel / end of the coating decreases, thereby in the same direction the resistance $ e area increases this coating. this variable in strength resistive coating can Innejoflache of the ceramic body member from one end to, completely cover the other end, thereby producing a gleichmäßigeres'elektrisches Field created within a given cross-section and a more uniform acceleration of the electron beam is achieved.

It is therefore an object of the present invention to provide an improved electron beam imaging device, which is a piston section made of augfceramisehem material contains.

Another object of the present invention relates to To provide an improved electron beam imager with a! piston »the one body section made of ceramic Material finthält, one end of which is hollow in cross-section and has the shape of a right-angled parallelogram and contains a faceplate section made of clear glass material, the shape of a flat plate with the shape of a right-angled corresponding to the transverse shape of the body Has an allelogue, as well as a closure or melt-in section for attaching the front panel attachment to the body attachment which consists of a material whose thermal

809806/0371

expansion coefficient similar to that of the ceramic material and of the transparent glass and its opening temperature substantially below that of the ceramic material and of the transparent glass.

Another object of the invention "relates to the creation an improved cathode ray tube that has a graduated scale has which. on the inner surface of a substantially flat, transparent glass front plate of the piston formed with the fluorescent screen above the graduated scale , is located and the front panel is designed so that light over the Unifangskanten into the front panel to illuminate the Stri.chbildes can be directed.

Another object of the invention is to provide an improved cathode ray tube having an anode coating of electrically _{resistive material containing Cr 2} O, Fe 1, Ti 0, and ceramic material, applied to the inner surface of a portion of the tube.

Yet another subject of the present. Invention relates an improved cathode ray tube, the piston 'a' non-carbon refractory electrical resistance coating Material on the inner surface of the funnel-shaped body part of the piston, the thickness of which changes depending on the distance from the front plate portion of the piston, and so that the thickness of the end facing the front panel increases to the end furthest from the faceplate, so that the resistance per square area of this coating is Indian the same direction decreases away from the front panel, this

809808/037 ι

Coating to create an electrical potential gradient is connected so that the coating as one after the deflection

the "located acceleration anode acts, the / electron beam" this cathode ray tube accelerated towards the front panel.

Still another object of the invention is to provide an improved bulb useful for a cathode ray tube to create, comprising: a neck portion made of glass with the shape of a hollow circular cylinder, a ceramic body portion, one end of which has a hollow, circular-cylindrical cross-section connected to this shaft part by means of a glass frit whose thermal expansion coefficient is essentially is the same as that of the ceramic body and the glass stem and the softening temperature thereof is substantially below that of the ceramic body and the glass stem, the ceramic body portion having a second end has a hollow cross-sectional shape in the shape of a rectangle, to which an Ixontplatte section made of transparent glass. consisting of -a flat plate, the shape of which corresponds to the second end of said body section, is connected by means of a glass frit, the heat of which is similar to that of the expansion coefficient ■ the / ceramic body and the Glass front plate is, and its softening temperature is essentially below that of the ceramic body and the ß-laser front plate lies.

Additional Subjects and Advantages of the Present The invention is based on the following detailed description of certain preferred embodiments of the invention the attached drawings.

809806/0371

In the drawings shows:. , -

Pig. 1 is a side view of an embodiment according to the invention

guide shape of a cathode ray tube;

Pig. Fig. 2 is a part of a plan view of the cathode ray tube according to Pig «1, in which part of the piston broke off shown is j

Pig. Figure 5 is an end view along line 3-3 in Pig. 1y Pig. Figure 4 is a section along line 4-4 in Pig * 3J Pig. 5 is a sectional view of part of the Grlas ceramic

y connection to the bulb of the cathode ray tube according to -., -: ■■■. Pig · 2j -. '".- ■

Pig. 6 is a partial sectional view taken along line 6-6

in Pig. 3t which one embodiment of the division of lines illustrated?

Pig. 7 is a partial view of the Pig. 6, which one another 'Illustrated embodiment of the division of lines j; ■■

Pig. 8 a part of a side view of another embodiment

management form of a cathode ray tube according to the invention j '*

Pig. 9 is a plan view of the cathode ray tube according to FIG

Pig. 8, shown broken off with parts of the piston aref

Pig. 10 is an end view of the cathode ray tube according to * ■■ .- ■ ^ Pig. 8 corresponding to line 10-10i

Pig. 11 a partial section after the line 11-11 in Pig. 8 and

Pig. 12 is a graph showing the resistance "-" characteristic of the variable resistance over-2ug illustrates which in the cathode ray tubes the pig. 8 to 11 is applied.

8G98GS / Ö37

An embodiment of the piston assembly according to the present invention is shown in fig. 1 ″ to 6 illustrates which can be found is that the cathode ray tube has a hollow, evacuated

Piston 10 made of electrically insulating material, which consists of an Irichter-shaped body section 12, a flat face plate section 14 and a cylindrical shaft section 16 consists. The piston 10 contains within the stem portion 16 a common electron beam system and common electrostatic Baffles (not shown), with electrical connected to the horizontal and vertical baffles Head 18 extend through a conventional melt point 20, the connects the two cylindrical parts that make up the shaft section form. Other electrical conductors 22 connected to the electrodes of the electron beam system extend through the end of the shaft section remote from the body section 12 16 and are held by a base 24 made of insulating material and fastened to the rear end of the piston 10. The body portion 12 of the piston is made of ceramic insulation and has the shape of a tapered which consists of those with a rectangular cylinder

material
Triohtere

connected truncated cone is formed and a smaller end with a has a hollow cross-section that is connected to the shaft section 16 eat and eat a larger egg with two, rectangular cross-sections, that is connected to the Froiitplatte 14, which The "n fluor" szenaeohirm 25 carries the cathode ray tube.

the in ienflache of the body portion of the piston can be a Wideretan Isschioht or a resistor coating 26 of essentially lichen gljBioh-shaped bead be applied, as shown in Pig.2 is shown, which is connected to the wide anode of the electron

809806/0371

ίο -

Beam system is electrically connected so that it serves as an extension of this anode and provides a substantially "uniform electric field within the body portion 12 for the electron beam in a cathode ray tube with" single acceleration ¹¹ . Two thin coatings 28 and 30 made of silver or similar conductive material can be applied over a short distance over the ends of the resistive coating 26 so that the outline of the effective anode is uniformly defined, which is formed by the coating gate electrical connection is established from the covering via a resilient Eragteil 31 with the second anode, as shown in FIG. 5. This uniform resistance coating 26 can consist of the usual material intended for low temperatures, such as Aquad or other carbon material, or it can be composed of a non-carbon, heat-resistant material, as will be discussed later with reference to FIG to 11 will be described.

The faceplate 14 may be a substantially flat rectangular one ! Plate made of clear, transparent glass material with the one shown in FIG. 5 and 4 be the shape shown, which on the larger end of the ceramic body part 12 fits »to which it is connected A graduated scale 32 can be provided on the inner surface of the faceplate 14 by drawing lines of frit on it prints and merges these lines with the faceplate before the coating of phosphor material forming the fluorescent screen 25 is applied. As shown in FIG. 6, this phosphor coating arranged above the graduated scale. Optionally, the striohlines chemically etched or mechanically as indentations 33 in the surface of the faceplate can be engraved as shown in

Fig. 7 is shown or it can be the dashed lines by a Paint made of light-reflecting material can be applied. By using a separate flat face plate 14, the Phosphor coating 25 and the graduation scale 32 applied to the face plate before this is connected to the Kolbenkörρteile 12, so that easier processing than the customary tubes made entirely of glass are possible.

The graduation scale 32 can be illuminated at the edges Obtain floodlighting) by placing a light source in the vicinity of an edge portion surrounding the periphery of the front panel 14 so that enough light is transmitted through the edge portion into the faceplate to illuminate the dashed lines. Am flange part 34 made of clear, transparent plastic or something similar Material in the form of a flat square plate can be attached to the edge of the faceplate using a transparent epoxy resin adhesive or the like can be attached when the light source is is at a location remote from the edge of the faceplate 14 (Fig. 3). This flange part wiikfc as a light guide, so that the light coming from the light source is effectively introduced into the edge of the faceplate. This flange part 34 can with two U-shaped recesses 36 and 38 in his • be provided on the upper outer edge section, which accommodate two incandescent lamps. The rest of the outer edge of this flange part With the exception of these recesses, a coating can be made of (not shown) light-reflecting material such as aluminum, silver or white enamel or lacquer in the usual way. If no flange part 36 is used, a such light reflective coating on the edge of the faceplate 14 can be advantageous.

809806/0371

The flat glass front plate 14 can be connected to the rectangular üinde of the ceramic body part 12 by means of a tight connection or melting point 40, which surrounds the fluorescent screen 25, so that the one shown in FIG butt abutting connection point is generated. This connection 40 can be made by a glass frit, whose coefficient of thermal expansion is approximately the same as that the ceramic material of the body part 12 and the glass of the front panel 14 and which has a softening or hardening temperature has, which are essentially below those of the ceramic material of the glass. To create the butt joint between the round end of the ceramic Body part 12. and the socket cut made of glass 16 of the piston may have another one similar to the connection 40 Connection 42 made of glass frit can be provided, since the socket section is made of the same material as the front plate 14 exist '(Fig. 5). Any suitable glass-ceramic system having the properties discussed above can be used will. For example, the body portion 12 may be made of forsterite ceramic material exist, which is composed roughly as follows in terms of weight:

Mg Ό ——— · $ 28

.Talk m —— $ 60

. Kaolin ———— 12 # : ^

The Irontplatte section 14 and the Stutzenaftschnitt 16 can made of soda-lime glass or ordinary lead glass as commercially available by Corning Glass Works as Corning Ko. 0080 or «0120 is available. The soda-lime glass has approximately that the following weight composition: - "

80980 6/0 371

Si O ₂ 73.

^ O- 16.

* ₂ υ τ -

Oa 0 5-2? 6

Mg 0 3 c

Al ₂ O ₅ ■ -— 1_.

100.

The glass ferit of the connection points 40 and 42 can be made from a devitrifiable glass, for example from a lead, zinc, borate glass as described in US Pat. No. 2,889,952 (SA Claypoole, June 9, 1959). This glass has a thermal expansion coefficient of approximately 93 χ 10 "are each C within the temperature range 25-450 ⁰ C. of the heat from-.dehnungskoeffizienten of Forsteritkeramik · is similar. The glass mentioned has a low softening temperature in the range 420-450 ⁰ C. Such a devitrifiable glass is available from the Corning Glass Works as "Pyroceram Cement ' ¹ No. 7572 is commercially available and can be used for joints or fuses 40 and 42 in the manner described in the aforementioned patent. ...

It should be pointed out that this devitrifiable glass is often referred to as "glass-ceramic" because it has properties that are similar to these two classes of material. However, the term "glass frit" used in the present application is also intended to include such devitrified glass. "Ceramic material are defined by ^w, that of the ceramic material" is intended to continue the expression used differs glass "means that the former is a crystalline material, while the latter is a supercooled liquid that is to say, a non-crystalline material.

809806/0371

Another embodiment of a cathode ray tube according to the invention is illustrated in FIGS. 8-11. This "compartment acceleration, ' ¹ cathode ray tube is similar to that of Figures 1 through 6 except that the uniform resistive coating 26 is replaced by a non-uniform resistive coating 44 of variable thickness. This coating 44 is on the inner surface of one funnel-shaped body portion 46 of the bulb, which has different dimensions and parabolically curved side walls from the body portion 12. In addition, a front plate 48 with a different shape is used, which does not contain a light guide flange 34 and has smaller height dimensions, so that the graduated scale 32 measures 6 cm by 10 cm compared to the reticle of 8 cm by 10 cm illustrated in Fig. 3. The variable calibrated resistance coating 44 changes its thickness from a maximum value near the nozzle section 16 to a minimum value near the front plate 48, thereby causing the resistance ever Cross-section of the coating in the same direction from a minimum value in the vicinity of the connecting piece section 16 to a maximum value in the vicinity of the front plate 48 is enlarged. The end of this stepped resistance lining 44 is connected to the second anode of the electron beam system in the vicinity of the socket section 16 of the piston in the same way as with the uniform resistance lining 26 by means of a spring part 31 and a guide lining 28 in the form illustrated in FIG the case is. The other end of this variable resistance coating is in the vicinity of the front plate 48 by means of an electrical connection 50, which extends through an opening in the body by section 46 of the piston, connected to a DC voltage source, which has a higher positive DC voltage than the second anode . It

80 9806/0371

is therefore along the surface of the variable resistance coating 44- an electrical potential gradient is obtained, so that this resistive coating is arranged as one after the deflection Accelerating anode acts, which increases the speed of the electron beam after it passes through the electrostatic Electrical signals supplied to deflector plates had been deflected. This electron beam therefore increases after the deflection its speed as it moves along the resistance and süb he trains in the direction of the Irontplatte 48 and moves produces an image with a higher light intensity on the fluorescent screen 25 without thereby reducing the deflection sensitivity of the tube will. ■

According to the illustration according to Hg. 11, the electrical connection 50 can consist of a solid plug 42, which consists of a ceramic material can be made, which is similar to that of the piston portion 46 and a coating 54 of electrically conductive material such as silver on its outer surface. This coated plug can be inserted into one on the piston section 46 in the vicinity of the conductive coating 30 is inserted and with the body portion through a vacuum-tight Terbindungsstelle 56 are connected from glass frit, the a composition similar to that for the joints 40 and 42 of this cathode ray tube operating with post-acceleration may have or may consist of another material suitable for a metal-ceramic bond. At the An additional silver coating 58 can be applied to the end of the stopper 52 after it has been attached to the piston section 46 had been »to make contact between the conductive coating 54 and the conductive coating 30, thereby preventing is that the glass frit 56 isolates the covering 54 from the covering 30.

80 9806/0371

143958 &

For the cathode ray tube that works with post-acceleration. = of Fig. 8 his-. It can be used a different ceramic-glass system. For example, the body portion 46 of the piston can be made of an alumina ceramic which has approximately the following composition by weight?

Al ₂ O ₃ '-> ---— _

Talk ——-._—————

Binding clay -.

Elaolite (fat stone) syenite (Nepheline Syeni te) 4 #

$ 100

The neck portion 16 and the faceplate portion 48 of the Piston can be made from a zirconium silicate glass, as is commercially available from Corning Glass Works, for example the. Designation Corning ITr. 7280 is available · This glass has about the following "composition by weight"

TTTTTTTTTTT

0, K ₂ 0

The connection points 40 and 42 can be made from a glass frit whose coefficient of thermal expansion is approx. 75 x 10 "" ^ cm per ⁰ C. in the temperature range from 25 to 70O ⁰ C and has a softening temperature below that of zirconium silicate glass. Such a glass frit is the Entglasbär® glass commercially available from the Corning Glass Works under the name `` Pyroceram Cement ¹⁸ Ir. "'754-1.

9-80 6/0 37 1

1Λ3958Β

discovered frits which can be assumed to have "so far is unknown. The weight composition of this new glass frit is as follows:

O $ 48

I ^υ 3 ". ■ ⁰ °

Si O ₂ 28%

B ₂ O ₃ 7%

Zn 0 -14%

$ 100

This new non-devitrifiable glass has a melting temperature in the range of 760 to 788 ⁰ O and a thermal expansion

-7 ο coefficients of approx. 65 χ 10 'cm each 0. in the temperature range

from 25 to 450 ⁰ O. cm

For proper operation as a post-acceleration anode, the resistance coating 44, which can be varied in its thickness have a resistance characteristic, di ^ sheoretic Ideal curve «60 after lig. 12 is similar. This curve shows the course of the resistance of the coating 44 as a percentage of the total resistance Status in connection with the measured from the surface 30 Distance in inches from the front panel. It should be noted that in the range of 0 to 1 inch a change in resistance; Available from around $ 17 while ranging from 7 to 8 inches only a change in resistance of about $ 7 occurs. The theoretical one Ideal resistance. per square of the coating 44 therefore increases a maximum value in the Kähe of the Erontplatte 48 up to one Minimum value in the vicinity of the nozzle section 16. Since the thickness changes inversely with the resistance, the theoretical '

809806/0371

ideal thickness of the coating 44 from a minimum value in the vicinity of the Eront plate 48 "to a maximum value in the vicinity of the nozzle section 16. It should be noted that the curve 60 represents only the theoretical ideal characteristic of the variable resistance coating 44, and that operable coatings can in reality have characteristic curves which are a few percent above or below this ideal curve. The total resistance of the resistance coating 44 can likewise be anywhere between 100 and 2,000 megohms for operable hearing. This total resistance is shown in the graph by the Resistance point $ 100 illustrated.

This variable resistance coating 44 can consist of customary Materials, such as A <luädag or other carbon materials. However, it has been found that these carbon coatings are damaged by the high temperatures used in the degassing process, so that they are unsuitable when extremely high temperatures are used, such as for efficient removal absorbed gases is necessary. The material of the changeable Resistance coating 44 or the uniform resistance coating 26 should therefore be a non-carbonaceous, heat-resistant. ge or refractory material, even at extremely high. Temperatures does not melt or suffers from oxidation. One such material has been discovered which is believed to be it has not yet become known. This; new resistance material has approximately the following weight ratio- settlementi.

80 9 80 6/037 1

2 ^{V <} Z _._ "---. MMMM - - Μ. Μ. - —Μ. —Μ. _ M. ^

Ii Ο «ρ

^ Μ «BB WMWBBBWWtM- Μ · MB WB BB BJ BB Μ · BB BM BM MM» Μ »BB M * M BB · -> ^ _

Feldspar $ 17.3

Tie tone ■ —— ~ 13.2 $

Flint · --— $ 14.3

Whipping Chalk (Recycled Ca Cq ) -15.2 $

100.0 $

It should be noted that this new resistive coating can basically be understood as a mixture of two different materials, namely (1) one from Conductive material made up of the first three ingredients listed - $ 40 total and (2) a ceramic material made from the. last consists of four ingredients listed - a total of $ 60. This resistive film can be applied using any common spray method applied and then heated »» so that he can with the The piston wall merges.

Various details of the embodiments described above of the invention can be modified without departing from the spirit of the invention. So can the nozzle section 16 are formed in one piece with the body sections 12 and 46, and thus also consist of ceramic material. That Front plate end of this body portion of the piston can be made in any desired dimension, so that a hollow Cross-section of any desired shape can be created, including a right-angled parallelogram in shape a square or rectangle. The front panel attached to it can likewise have any conventional shape.

809806/037 1

The light guide flange 34 can be integral with the front panel be formed so that it is also made of glass. The light guide flange 34 can also be omitted completely. the butt joints formed by the bin fuses 40 and 42 can be designed differently. For example, the melting point 42 can have the shape of a sliding joint. It is therefore intended that the scope of the present invention be determined only by the following claims.

809806/037 1

Claims (1)

Claims . JKolbenaafbsm XUr an electron beam forming device, made by one made of ceramic material hollow tubular piston body section, one of which is 3m * This body cover is made of translucent glass and consists of a seed A flat plate adapted for bathing the body section as well as through an "annuity plate section with one end of the Xkörperabsohaittes Terbindenden Biohtungsabsohnittes for the TsJnm »- tight seal dee one end ·. 2. LolbensÄfbau make claim 1, characterized in that the an effeme Xade of the body technique · in cross-section hollow and is essentially rectangular and that the sealing section is made of a material whose thermal expansion is efficient within a wide temperature range in the Wesemtjiiehe »with that of the · ceramic material · and des Uohtädwohlaseige »Olasee. 3. KftlseaUftfeau maeh iasendung t or 2 »marked thereby, α «! the atehtungisasechnitt consists of a bucket of oil asXritt »their irweietem ^ tertite under the softening temperatures of lreTam1sol # n material and the translucent oil gas. 4 · telsemWtfseai mil Amsprueh 3, dadmreh «ekennseichmet» daJ di · contains emtglaatee Olas. BAD cniSVi-i ^ L 809806/0371 5. Piston structure according to claim 3 »characterized in that the · Glass frit made up of the following components by weight approximated as follows ^ · * ■ * Si O ₂ Zn ο 6. Piston structure according to one of the preceding claims, characterized in that an anode coating made of electrical resistance material is applied to the inner surface of the piston body section, which is made up of Ti O ₂ * Fe ₂ Q ^ · Or ₂ O "and ceramic Contains material. 7 · Kolbenauflbau by a "· τ ά preceding Aneprüoh · 1 to 5, characterized in that" the existing DAFL of electrically resistive material AnodenübersEug is attached to the inner surface of XolbenkOrperteiles "check that changes along its thickness, the surface of the Körperabechnlttes" 8 · Piston structure according to claim 7 »characterized» in that the piston body section decreases in its »cross section from one« oest value at one end to the other end and that the thickness of the inode cover varies from a minimum value to one end of the body section «» The lower end of the upper suction to the maximum value at the opposite end changes in such a way that the resistance per square of the coating is suniaat from the end with the greatest biake at the second bead with the smallest bead. 809806/0371 9. Piston assembly according to claims 6, 7 and 8, characterized thereby indicates that the resistor material is composed by weight of the following components approximately as follows is: Fe ₂ O, 35. il U ₂ - - - ^. Feldspar. 17.35 ^ Binding clay $ 13.2 Flint $ 14.3 Mud chalk $ 15.2 10. Piston structure according to claims 6, 7 and 9 »characterized in that that in an opening arranged in the vicinity of the resistance coating an electrically conductive material coated Ceramic plug is attached with a tight seal and that one is in contact with the resistive coating and the coating of conductive material standing conductive coating is applied to the inner surface of the body portion, so that an electrically A conductive connection is made from the outside of the piston to the resistance coating located inside the piston. 11. Piston structure according to one or more of the preceding Claims, characterized in that the end plate section of the piston has a line division on its inner surface, so that this is located inside the piston assembly and that the end plate portion contains means which for Illumination of the division of lines Light projected from the outside of the bulb through the edge of the faceplate. 809806/0371 12. Piston structure according to claim .10, characterized in that the line division consists of melted glass lines, which are applied to the inner surface of the faceplate. 13. Piston arrangement according to claim 10, characterized in that the division of lines notched into the inner surface of the faceplate Lines. 14. Piston arrangement according to one of claims 11, 12 and 13 »thereby characterized in that the device which projects light through the edge, one with its inner edge with the edge the end plate connected to the flange part made of translucent Contains plastic material that acts as a light guide or conduit. 15. · Piston arrangement according to one of the preceding claims for Use for a cathode ray tube, characterized by that it contains in combination: a fluorescent screen attached to the inner surface of the faceplate and located inside the envelope; one of the front plate located away inside the piston nen
Jölektro / source; Devices which accelerate the electrons and focus them into an electron beam; and devices which deflect the electron beam as a function of an electrical signal before it hits the fluorescent screen 809806/0371