DE3304724A1 - Cathode ray tube - Google Patents

Abstract

In order to improve the brightness uniformity of a cathode ray tube having an aperture diaphragm, it is proposed to screen the section of the electron beam lying in front of the aperture diaphragm from the deflection field.

Description

description

Cathode Ray Tube The present invention relates to a cathode ray tube with a fluorescent screen arranged in a space free from electrical fields Aperture diaphragm that limits the cross section on the circumference, one between the fluorescent screen and aperture diaphragm arranged magnetic deflection device for deflecting the electron beam limited in cross-section over the fluorescent screen and a magnetic one Shielding cylinder shielding fields, covering the tube, the deflection device and surrounds the aperture stop.

In particular, the invention relates to a cathode ray tube with high resolution, in particular a tube in the manner of a fine point tube or an IR scanner.

Tubes of the type mentioned are already known.

They have to reduce the cross section of the electron beam a so-called aperture diaphragm, which is made by an electron beam with a larger cross-section only lets through a central cross-sectional part. This aperture diaphragm is located in an electrically field-free room. This field-free space becomes more common Way generated by a tubular so-called focus electrode, which in comparison has a large length to its clear cross-section, so that no electrical Fields can intervene in the area of the aperture diaphragm.

The deflection of the electrode beam over the target electrode, which at a fine point tube z. B. is a fluorescent screen, is done with the help of deflection coils, which are located on the outside of the vacuum envelope of the tube. The entire tube, including the deflection coils, is located in a magnetic shielding cylinder, the magnetic fields from the inside of the tube and at the same time a return for the magnetic Forms field lines.

It has been shown that when scanning tubes of the aforementioned type of the electron beam fluctuations in the intensity of the luminous point on the luminescent screen are detectable.

The present invention is therefore based on the object of reducing brightness fluctuations of the light spot depending on the position of the same on the luminescent screen reduce and additionally increase the distraction sensitivity.

This object is achieved according to the invention in that a Aperture diaphragm surrounding shielding tube made of ferromagnetic material of such training it is provided that the part of the electron beam lying in front of the aperture diaphragm largely unaffected by the cathode-side magnetic field of the deflection device remain.

By attaching a ferromagnetic shield with high Permeability in the area of the aperture stop becomes not just one of the deflection dependent fluctuation in brightness largely prevented, but it is thereby also causes an increase in the deflection sensitivity, since an improved return of the magnetic flux is achieved. The undesired reduced according to the invention or eliminated fluctuations in brightness are obviously caused by that in known arrangements the deflection field also on the beam part in front of the aperture stop acts. Although the cross section of the beam is sufficiently large there, the Inentsity of the transmitted electron beam evidently through a slight Deflection of this beam part affects, because the electron density is related to the electron beam cross section is not evenly distributed, but after a "Gaussian curve" runs as a function of the radius.

Based on the preferred embodiment shown in the figure the invention is explained in more detail below.

The figure shows schematically a cross section through the most important Parts of a fine point tube. On one end of the vacuum envelope made of glass 1 there is a light screen 6 on which the aperture diaphragm is exposed 12 passing electron beam 7 generates a luminous point.

The electron beam is generated on the emission surface of the cathode 13 and is formed in its shape by the electrodes 9, 10 and 11 so that a diverging beam part 8 is created, the cross section of which is larger than the opening in the aperture blender 12.

The focus electrode il has a length compared to the cross section is large so that the aperture diaphragm 12 located therein is in the electrically field-free Space is located. There are between the focus electrode 11 and the luminescent screen 6 on the outer surface of the vacuum envelope 1 deflection coils 5, with the help of which the electron beam 7 can be deflected in the form of a stitch or grid over the luminescent screen 6. Both the deflection coils 5 as well as the essential part of the entire tube are with a shielding cylinder 2 surrounded by ferromagnetic material.

The stray field on the cathode side of the deflection coils 5 can now at least partially also on a part of the electron beam section lying in front of the aperture diaphragm 12 8 act and z. B. back and forth in the case of a line-shaped deflection will. This beam part 8 becomes a different cross-sectional part hidden through the opening of the aperture diaphragm 12, which obviously also a has different electron density, resulting in a different brightness of the light spot on the luminescent screen 6 results. To now these fluctuations in brightness According to the invention, the aperture diaphragm 12 is to be avoided by a shielding tube 3 made of good ferromagnetic material, such as. B. Mu-metal surrounded. This shielding tube 3 keeps the stray fields of the deflection field of the deflection coils 5 on the cathode side the beam part 8 away. The cathode side preferably has end this shielding tube 3 has an outwardly directed Rinflansch 31. Through this the magnetic return of the deflection field is further improved and the deflection sensitivity increased.

According to a further embodiment, it is useful for the fluorescent screen side End of the deflecting shield tube 3 towards an inwardly projecting magnetic ring flange 4 to provide a more concentrated return in this area and thus a causes indirect amplification of the deflection field on the electron beam 7. By the shown formation of the shielding tube 3 are the magnetic back yoke field lines, which would otherwise act on the beam part 8 in front of the aperture diaphragm 12, taken up by the shielding tube 3 and shifted into the cross section of the annular flange 4.

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Claims (6)

Claims Qi cathode ray tube with a fluorescent screen a in a space free from electrical fields arranged aperture stop that on Circumference limits the cross-section, one arranged between the luminescent screen and the aperture diaphragm magnetic deflection device for deflecting the electron beam limited in cross section via the fluorescent screen and a shielding cylinder that shields magnetic fields, surrounding the tube shell, baffle and aperture stop thereby characterized in that a shielding tube (3) which surrounds the aperture diaphragm (12) is made of ferromagnetic Material of such a design is provided that the one in front of the aperture diaphragm (12) Part (8) of the electron beam from the cathode-side magnetic field of the deflector (5) remains largely unaffected. 2. Cathode ray tube according to claim 1, characterized in that the shielding tube (3) is arranged inside the tube casing (1). 3. Cathode ray tube according to claim 2, characterized in that the shield tube is attached to a cylindrical electrode (11) inside which the aperture diaphragm (12) is arranged. 4. Cathode ray tube according to one of claims 1 to 3, characterized in that that at or near the cathode-side end of the Abschlrmrohrs (3) an annular Material thickening, in particular an outwardly facing annular flange (31) is provided is. 5. cathode tube according to one of claims 1 to 4, characterized in that that at or near the end of the shielding tube (3) on the fluorescent screen side an annular ITTO-magnetic screen, in particular an inwardly facing annular flange (4) is provided is. 6. Cathode ray tube according to one of claims 1 to 5, characterized through its application and training as a fine point tube.