DE2214374B2 - Image converter or image intensifier tube - Google Patents

Description

The invention relates to an image converter or image intensifier tube with features as in the preamble of claim 1 described in more detail.

In such an image converter or image intensifier tube, one makes the adjustability of the on voltage to be applied to the tube to adjust the intensity of the image generated by the fluorescent screen Use. It is used in particular when it comes to the reproduction of X-ray images acts and if the image intensifier tube is used to amplify X-ray images and to do so with a Entrance luminescent screen is provided, which converts the X-rays into light and with the rnötökathode is optically coupled The intensity control of the image produced by the electron trapping luminescent layer is important if it is to adapt to the eye or to a television pickup tube coupled to the image intensifier tube acts and if the regulation of the image rays captured by the image intensifier is undesirable or not possible, which often happens when working with X-rays.

With the intensity control by setting the Operating voltage you can practically not reduce this operating voltage further than up to about Half of the nominal operating voltage of the tube, because the electron-optical system is then insufficient sharp image results in more. The acceleration voltage is below the nominal operating voltage of the tube understood between the photocathode and the cover layer that the correct imaging guaranteed and on soft c'ir tube structure (arrangement of electrodes, including the photocathode and the electron-capturing luminescent layer with cover layer) is matched.

In the known image converter or image intensifier tubes of the type mentioned at the outset, regulation is carried out the voltage from the nominal operating voltage to about half of the same has an intensity ratio of the luminous image generated by the electrons of about 1 to 1/3 realizable, which has been proven is often too little.

The object of the invention was to provide a measure with which the control range of mentioned intensity is increased considerably. This measure is based on the knowledge that the The above-mentioned object can be achieved by such a design of the cover layer, in which at always As the operating voltage of the tube is further reduced, an ever larger part of the amount arriving at the top layer Electrons lose their energy in this top layer.

In order to achieve the stated object, therefore, in the case of an image converter or image intensifier tube, the mentioned type measures taken, as described in more detail in the characterizing part of claim I. In a further embodiment of the invention, measures can be taken, as in the codes the subclaims described in more detail.

The invention is illustrated by some in the drawing

illustrated embodiments explained in more detail. It shows

Fig. 1 is a schematic representation of an arrangement with an X-ray image intensifier and a adjustable operating voltage,

F ί g. FIG. 2 is a graph showing the relationship that exists in a conventional X-ray image intensifier and in FIG various X-ray amplifiers according to the invention between the operating voltage on the Tube and the luminescence of the luminous layer consists.

In the case of the in FIG. 1 shown in a schematic manner Arrangement are X-rays emitted by an X-ray tube 1 from the input screen 4 an X-ray image intensifier tube 3 after they have passed an object 2 to be examined. This tube 3 with the glass bulb 5 has a curved front surface 6, on the inside of which Input screen 4 is applied This input screen 4 consists of a directly on the glass Front surface 6 provided luminous layer, 7, a thin, transparent separating layer 8 and one for the Luminescence light of the layer 7 sensitive photocathode layer 9. At the other end of the Kobens 5 is the The tube is provided with an output glass 10, on which an output screen 11 with a luminous layer 12 is provided which layer on which the input screen the facing side is covered by an electrically conductive and impermeable cover layer 13 is. The output screen is surrounded by and electrically connected to a funnel-shaped anode 14. At A circular intermediate electrode 15 is also located on the inner wall of the piston 5.

A voltage source 20, which is bridged by a resistor 21 designed as a potentiometer, is provided for the electrical supply of the X-ray image intensifier tube 3. The photocathode 9, the intermediate electrode 15 and the anode 14 with the output screen U are all connected to this potentiometer, the photocathode being connected to an adjustable contact 22 and the anode 14 together with the output screen 11 to an adjustable contact 23. The intermediate electrode 15 is connected to a fixed point of the potentiometer 21, as a result of which this intermediate electrode 15 has a positive potential of 200 to 250 volts with respect to the photocathode 9. The positive voltage (tube voltage) V which the anode 14 together with the output screen 11 carries with respect to the photocathode 9 is; from the voltage of the voltage source VO - which is equal to the nominal operating voltage V _{n of} the image intensifier tube 3 or slightly higher - adjustable up to about a quarter of the same. The nominal operating voltage V., of an image intensifier tube is understood to be the voltage to be applied between the photocathode and the luminous layer collecting the photoelectrons, which results in the best electron-optical image of the photocathode on the luminous layer with the given tube arrangement.

By adjusting the tube voltage V by adjusting the contacts 22 and 23 - the former for Adaptation of the voltage difference between the photocathode 9 and the intermediate electrode 15 to the changing tube voltage - the intensity of the generated by the luminous layer 12 can be Change dildes.

In this respect, the arrangement according to FIG. 1 differs. I not known by! Arrangements.

In these known arrangements, the cover layer 13 is on the luminous layer 12 by a thin Layer of vapor-deposited aluminum formed with a thickness of 100 to at most 300 nm, with about 125 nm is common

In the first respect, such a layer, which is also generally used in television reproduction and other cathode ray tubes with a cathodoium inescent layer is common, which is through the luminescent layer

ίο to reflect light emitted to the top layer. In secondly, it aims to divert the electrons hitting the output screen while such a layer further to prevent the interaction between the photocathode material, for example cesium, and the luminescent layer material can serve. A layer of aluminum with the The above-mentioned thickness of 300 nm is penetrable for electrons with a speed of 3 to 4 kV. In general, the penetration depth 5 of electrons into a material has the following formula enough:

S =

CV ¹

where C is a constant, P is the specific gravity of the layer material and V is the voltage with which the electrons are accelerated when they reach the layer.

With a corresponding FIG. 1 executed image intensifier tube, the cover layer 13 is actually thicker than usual, and it can also consist of different materials. The decisive factor is that this cover layer is less penetrable for electrons than the usual cover layer, so that electrons originating from the photocathode 9 only penetrate the cover layer and the luminous layer lights up when the tube voltage is higher than the acceleration voltage of 3 to 4 kV mentioned above 12 can cause. According to the invention the top layer 13 must be formed so that, Photoeiektronen cause luminescence only at a tube voltage V, which is a quarter of the nominal operating voltage V _n; this should preferably only occur at a tube voltage which is between 50 to 80% of the nominal operating voltage V _{n of} the image intensifier tube 3.

The effect of the measure according to the invention is illustrated in Fig. 2, in which the change of the output screen is plotted as a function of tube voltage V for cover layers with different penetration of the photoelectrons in the luminescence /, wherein the luminescence at the nominal operating voltage V _n are each equal to 1 is set. For BildversiärkcTöhrcn, Üb'ir.h is a nominal operating voltage of 22 to 25 kV; F i g. 2 relates to an X-ray image intensifier: r with V _n = 25 kV.

In Fi g. 2, curve a applies to an X-ray image intensifier with the same aluminum cover layer with a thickness of 100 to 200 nm, curves b, c and d apply to X-ray image intensifiers in the arrangement according to the invention. Curve b applies to an X-ray image intensifier with a cover layer consisting of an aluminum layer approximately 1000 nm thick, which only becomes permeable to electrons when they are accelerated to more than approximately 8 kV. The curves c and d are for the image intensifier whose outer layer zr% \ is then penetrated by electrons. if this is more than about 12.5 kV. ie half of the nominal

Operating voltage V _n or more than 16 kV are accelerated.

When operating a based on FIG. In the arrangement described it is practically impossible to make the tube voltage V lower than half the nominal operating voltage V _n if one still wants to have an acceptable image quality. This is linked to the electron-optical properties of the image intensifier. With respect to FIG. 2 this means that in practice the luminescence of the luminous layer 12 of the image intensifier can only be achieved by changing the setting of the tube voltage in accordance with that part of the curves; /. b, c and d can regulate.

to the right of the dashed line V = ^ ^ " ^M ' ^e ?' · If the luminescence control range is the ratio of the luminescence at nominal operating voltage V _n to the minimum luminescence to be obtained without the tube voltage being half of the nnminnlpn Rpctriphssnannijna ij; ** £ ri: Chrii! Ten ? \\ ! ;;. ^Ι , ^ ΟΠ.

so shows l · 'i g. 2 clearly shows that such a control range in the known image intensifier (curve a) is approximately 3. In the case of the image intensifier, which is provided with a 1000 mm thick aluminum cover layer, this control range is about 10, while it is for such image intensifiers. for which curves c and d apply, is still considerably larger and can even be 100 in practice. The measure according to the invention therefore creates a considerably greater possibility of regulating the adaptation of the luminescence of the output screen to, for example, the eye or a television pickup tube than is possible with the known arrangements.

Because the application of b / v .. vapor deposition of an aluminum cover layer with a thickness that is greater than about 1000 nm results in difficulties, it is desirable to use other types of cover layers that are only penetrated by electrons accelerated to more than 8 kV Way to form. So can other metals, such as titanium. Silver. Lead, and especially gold, can be used, while it is often beneficial in preventing contamination. to apply a thin aluminum layer on the side of the photocathode and sometimes on the side of the luminous layer. In such a case, the top layer consists of different sub-layers. An example of this is

^r > a top layer consisting of three partial layers namely a first, about 100 nm thick aluminum layer directly on the luminous layer, on this aluminum layer a gold or lead layer with a thickness of 300 to 600 nm and on top a second aluminum layer

ίο with a thickness of, for example, about 60 nm. Eir Another example is a titanium layer approximately 120 nm thick an aluminum directly on the luminous layer and then on the side facing the photocathode 9 layer of about 100 mn. As a guide at de

Ii Determination of the required thickness of a Schiclv or partial layer that applies to electron absorptior equivalent thicknesses of different materials behave inversely like the specific gravity Materials. Another way to do it

_-G chüilg Cincr top layer e-fiiSprcCneüu utri ciiuiuuiigs appropriate measure consists in the use of metal oxides. like titanium monoxide (TiO), specific Weight 4.93 (almost twice as high as before aluminum) and titanium dioxide, specific gravity 4, Γ

.'Ι or 3.84 depending on the modification. One changes There is a possibility of using a partial layer of luminous material, for example the same as in FIG the luminous layer 12 was applied, but without assets? ..r. thereby making this material electrons without

jo light emission absorbed. As suitable for this Material can be called zinc cadmium sulfide (ZnCdS) without an activator whose specific weight (= about 4.5) is slightly more than one and a half times that of aluminum. As an example, consider one of two

)) Called sub-layers of existing top layer 13, namely from a first, directly adjoining the luminous layer 12, and from one For example, obtained by deposition partial layer of zinc cadmium sulfide consisting of a layer

jo thickness of about 1500 nm and one over it th aluminum layer with a thickness of 50 to 100 nm.

1 sheet of drawings

Claims (10)

Claims; 1. Image converter or image intensifier tube with an input screen that is a photocathode and with an output screen having a luminous layer and on which the photocathode facing side a cover layer made of an electrically conductive, opaque material and for collecting the emanating from the photocathode by means of an operating voltage accelerated electrons, characterized in that the material and the thickness the cover layer are chosen such that the cover layer at an operating voltage which is lower than a quarter of the nominal operating voltage of the image converter or image intensifier tube, practically no more electrons can pass through, which cause the luminous layer to light up. 2. Image converter or image intensifier tube Claim j, characterized in that the Material and the thickness of the top layer such are chosen that the luminescent layer only at between 50 and 80% of the nominal operating voltage the operating voltage of the image intensifier tube lights up. 3. image converter or image intensifier tube according to claim 1, characterized in that the Cover layer consists of an aluminum layer with a thickness of about 1000 nm. 4. image converter or image intensifier tube according to claim 1, characterized in that the Cover layer is formed from several adjoining partial layers, of which at least one made of metal b-sestand 5. image converter or image intensifier tube according to claim 4, characterized in that the Cover layer consists of two aluminum layers with a gold layer in between. 6. image converter or image intensifier tube according to claim 5, characterized in that the Cover layer made of an aluminum layer adjoining the luminous layer and having a thickness of about 100 nm with a gold layer provided over it with a thickness of 300 to 600 nm and 4ΐ finally, on the side facing the photocathode, made of a second aluminum layer with a Thickness of 50 to 100 nm. 7. image converter or image intensifier tube according to claim 4, characterized in that a Sub-layer of the cover layer made of non-activated luminous material adjoining the luminous layer, For example, ZnCdS is made, which does not emit light when penetrating from the photocathode having electrons originating from. 8. image converter or image intensifier tube according to claim 4, characterized in that the Cover layer contains a partial layer consisting of a metal oxide. 9. Image converter or image intensifier tube according to f> o Claim 8, characterized in that the partial layer consisting of metal oxide is made of titanium oxide consists. 10. image converter or image intensifier tube according to claim 4, characterized in that the Cover layer made of at least one aluminum layer and a partial layer made of a different material consists. II. Image converter or image intensifier tube after Claim 10, characterized in that the partial layer made of another metal from a Metal belonging to the group titanium, silver and lead is made up of.