DE1439720B2 - CATHODE TUBE WITH DEFLECTORS - Google Patents

Description

The invention relates to a cathode ray tube with deflection means, with a first imaging lens for generating an intermediate image of a beam cross-section, in particular the beam crossing point and with one of the deflection amplifications, the second imaging lens is used to image the Z. image on a target electrode, which is preferably designed as a luminous slide.

With the usual cathode ray tubes, such as t for example in oscilloscope tubes, the in e; Distance in front of the cathode surface of the beam crossing point with the help of an image lens shown on the luminescent screen. Between /

ίο educational lens and luminescent screen are means of graduation Kung of the electron beam arranged in two mutually ser right directions. It is also possible between the deflection means and the light bar, there are still further electrodes for the so-called night provide acceleration of the electron beam.

In FIG. 1 is a schematic of the beam path eir usual oscilloscope tube. E electron gun 1 brings an EIe tron beam emerges with a beam crossing point. An imaging lens 3 is used to electr to focus the inner beam on the luminescent screen 4, d. the cross section of the beam crossing point 2 a the luminescent screen 4 to map. The Bren point planes of the imaging lens 3 are denoted by / i. On d Imaging lens 3 is followed by deflection means 5 and 6 ζ deflection of the electron beam over the lamp screen 4. From the schematic representation it can be seen that the degree of deflection of the electron; The beam on the luminescent screen depends on the distance of the luminescent screen from the center of the deflection and the deflection angle. With a given maximum deflection angle, the size of the fluorescent screen is durc determines its distance from the deflection means. B · the practical application, this affects the We It is assumed that the overall length of the tube is greater, the larger the screen is. One common Post-acceleration of the electron beam even makes part of the deflection of the beam reversed, since the collecting effect of an electrc static post-acceleration field removes the electron deflects the beam back towards the tube axis by a certain amount.

From the DT-AS 10 98 627 it is already known with by means of two cylindrical lenses only in one deflection.

to cause a beam deflection, it is assumed that it is in rotationally symmetrical formation tion of the lenses is practically impossible, the deflection organs for the two deflection directions one behind the other to be arranged on the tube axis.

The invention makes it its task to provide a cathode ray tube that is the same odei shorter overall length larger deflections de; Electron beam allows without an increase in the applied distraction occurs. In other words, the object of the invention is to provide a To construct cathode ray tubes with increased deflection sensitivity without compromising on the electron-optical Properties such as opening errors, distortion errors, etc. accepted disruptive disadvantages would have to be.

According to the invention it is proposed that the first imaging lens is designed such that the Intermediate image at most an image that is twice as large, preferably an image of approximately the same size or smaller of the radiation crossing point is that the refractive power of the second imaging lens is greater than that of the first imaging lens and that the first and the second imaging lens are rotationally symmetrical

det are.

It has been found that, taking into account all factors such as overall length, required deflection power, Opening errors, distortion errors, etc., an optimal effect occurs when the beam crossing point is mapped in the plane of the intermediate image on a scale of 1: 1 or smaller. Above all a minimal overall length of the tube can be achieved if the intermediate image is an image of approximately the same size of the ray crossing point.

On the basis of the FIGS. 2 to 6 illustrated preferred embodiments of the invention is the Subject of the invention explained in more detail below.

The F i g. 2 schematically shows the electron-optical structure of a cathode ray tube. The electron beam is produced by a beam generating system 21. Some distance from that In the beam generation system, the beam crossing point 22 is formed. A first imaging lens 23 forms the beam crossing point in a plane that is not on the screen, but a greater distance is in front of the luminescent screen 24. The image is shown at a maximum of 1: 2, but preferably on a scale of 1: 1 or smaller. A 1: 2 scale image will generally be larger Distortion errors occur whose compensation is relatively difficult and expensive. The distortion errors of the intermediate image generally become the first as the magnification increases The imaging lens is larger, which is why an enlargement beyond the scale of 1: 2 does not make sense, especially since it also leads to an extension of the tube.

The intermediate image advantageously represents an image of the ray crossing point. However, it can also be possible to map a different beam cross-section, for example the beam cross-section in one Aperture stop or a cathode spot.

In the beam direction behind the plane of the intermediate image 28, a second imaging lens 27 is provided, which depicts the intermediate image 28 on the luminescent screen 24.

Deflection means 25 and 26 are again provided in a known manner. The focal planes of the first imaging lens 23 are denoted by / 1 and those of the second imaging lens 27 are denoted by / 2. If the second imaging lens 27 is designed as an electrostatic acceleration lens, the screen-side focus of the second imaging lens 27 shifts in the direction of the screen, for example in the plane designated by ti.

In the case of the FIG. 2, the deflection means 25 and 26 are behind in the beam direction of the first imaging lens 23 is arranged. The first imaging lens can, however, as in FIGS. 5 6 and 6, either between the deflection means or after the deflection means. The deflection means are in the form of electrostatic deflection plate pairs, as are common with oscillograph tubes, shown. But they can also be designed as magnetic deflection means.

A comparison between a known arrangement according to FIG. 1 and the arrangement according to FIG. 2 shows that with the same overall length, d. H. So with the same distance from the beam generation system to the fluorescent screen, the The electron beam describes a much larger area of the fluorescent screen, the angle at which the deflection means deflect the electron beam, was not enlarged. So in other words that means that less deflection of the beam is required within the deflection means around a tube of the same length and the same screen diameter to be written out in full.

The second imaging lens 27 has a greater refractive power than the first imaging lens 23. Although it is particularly advantageous to design the second imaging lens as an electrostatic lens, thus both or one of the two lenses can also be designed as magnetic lenses. So it is special It is expedient to design the second imaging lens as a so-called electrostatic acceleration lens. Such an electrostatic accelerating lens is shown schematically in FIG. 4 shown. It consists z. B. of two consecutive cylindrical pipe sections, of which the one seen in the direction of the jet second pipe section is applied to a higher voltage than the first. Such a lens is therefore special expedient because it fulfills two tasks, namely on the one hand the task of mapping the intermediate image on the luminescent screen and, on the other hand, the post-acceleration of the electron beam. Included It is very advantageous that any post-acceleration is carried out with this second imaging lens can be without thereby reducing the deflection sensitivity, as in disadvantageous This is the case with the known oscilloscope tubes with post-acceleration spiral on the inside wall of the tube the case is. Rather, a higher post-acceleration ratio also increases the refractive power the second imaging lens and thus inevitably an increase in deflection sensitivity.

Both the imaging lens 23 and the imaging lens 27 are rotationally symmetrical lenses educated. If necessary, it can be expedient, for example for the purpose of a further reduction from distortion errors to provide the second imaging lens 27 with additional auxiliary electrodes.

The F i g. 3 schematically shows an electrostatic three-electrode lens constructed in accordance with a single lens; whose middle electrode is negative or positive compared to the two outer electrodes Has potential. It is common, but not necessary, to put the two outer electrodes at the same potential to be laid (symmetrical or asymmetrical potential generation). As such, three-electrode electrostatic lens the first imaging lens 23 will preferably be formed. Especially if the first imaging lens is arranged in the beam direction in front of the deflection means, because one in the area of Deflection means want to avoid an overly accelerated electron beam as possible. Such a three-electrode lens can also be used as the second imaging lens 27. It can thus have the same advantage achieve an increased deflection sensitivity. An additional acceleration of the electron beam can, however, only be achieved with an asymmetrical potential, in which the last electrode is on There is a more positive potential than the first electrode, viewed in the direction of the beam.

1 sheet of drawings

Claims (11)

Patent claims: 1. Cathode ray tube with deflection means, with a first imaging lens for generating a Intermediate image of a beam cross-section, in particular the beam crossing point and with a the deflection amplification serving second imaging lens for imaging the intermediate image a target electrode preferably designed as a fluorescent screen, characterized in that that the first imaging lens is designed such that the intermediate image is at most twice as large large, preferably approximately the same size or smaller image of the beam crossing point is that the refractive power of the second imaging lens is greater than that of the first imaging lens and that the first and the second imaging lens are designed to be rotationally symmetrical. 2. Cathode ray tube according to claim 1, characterized in that one or both imaging lenses are designed as electrostatic lenses. 3. Cathode ray tube according to claim 2, characterized in that the first imaging lens as electrostatic single lens is formed. 4. Cathode ray tube according to claim 1 or one of the following claims, characterized in that that the second imaging lens is designed as an electrostatic acceleration lens. 5. Cathode ray tube according to one of claims 1 to 4, characterized in that the second Imaging lens has at least one additional auxiliary electrode. 6. Cathode ray tube according to one of claims 1 to 5, characterized in that the second Imaging lens is designed as an electrostatic single lens. 7. Cathode ray tube according to one of claims 1 to 6, characterized in that the first Imaging lens is arranged in the beam direction in front of the deflection means. 8. Cathode ray tube according to one of claims 1 to 6, characterized in that the first Imaging lens is arranged in the beam direction behind the deflection means. 9. Cathode ray tube according to one of claims 1 to 6, characterized in that the first Imaging lens is arranged in the beam direction between the deflection means, in the beam direction offset deflection means for deflecting the electron beam in two mutually different Levels are provided. 10. Cathode ray tube according to one of claims 1, 2 or 4 to 9, characterized in that the first imaging lens is designed as a magnetic lens. 11. Cathode ray tube according to one of the claims 1, 2, 3 or 7 to 10, characterized in that the second imaging lens is a magnetic lens is trained.