NL8201929A - CATHODE JET TUBE WITH LIQUID COOLED SCREEN AND WITH ONE OR MORE SUCH CATHODE JET TUBES. - Google Patents

Description

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Cathode ray tube with liquid-cooled display and device equipped with one or more such cathode ray tubes.

The invention relates to a cathode ray tube with a liquid-cooled screen and to a device equipped with one or more such cathode ray tubes.

More particularly, the invention relates to such a cathode ray tube or device, which provides a high image clarity, for example for use in: a color image projector.

In such a color image projector, as shown in Fig. 1 of the accompanying drawing, for example, use is made of three monochromatic cathode ray tubes R, G and B with respective red, green and blue color phosphor layers? these cathode ray tubes project three monochromatic images onto a projection screen 21 via respective optical systems 20R, 20G and 20B.

The monochromatic cathode-ray tubes R, G and B of monochromatic type used with such a color image projector, and more particularly the cathode-ray tube G serving for the formation of a green image, must be such as to obtain a clear color image on the projection screen 20 21 itself. they have a large image clarity of their own.

Such a cathode ray tube is operated in such a way that the energy of the electron beam directed at the phosphor screen of the tube has such a high value that a color image of high brightness is obtained. Since the front panel, on which the color phosphor layer is applied, shows a low heat conductivity, and this in particular during continuous operation of the cathode ray tube, the temperature in the center of the front panel will reach a very high value. As a result, a thermal effect (quenching) can occur in the color phosphor layer, the brightness of the phosphor layer, or the image produced thereby, decreasing as the temperature increases. Since this thermal effect differs for different colored 8201929 1 i - 2 -% phosphor layers, it causes a distortion of the white balance of the color image projected on the screen 21.

This white balance disturbance, which occurs more particularly at the heart of a color image projected on the screen 21, has a noticeably detrimental effect on the quality of the displayed image. Although it could be considered to adjust the brightness of the individual color images in the edge portion of the color image formed on the screen during continuous operation of a projection device constructed with such cathode ray tubes such that the entire color image has the same white balance as in the heart, the problem then arises that not only is the white balance in the edge portion of the projection screen changed, but the desired, substantial image brightness is not obtained for the entire color image.

In connection with this, during continuous operation of such a cathode-ray tube or a device equipped with such cathode-ray tubes, it is necessary to use forced cooling of the front panel of the cathode-ray tube. For example, a cooling fan can be used, the effect of which counteracts the aforementioned thermal effect. The use of such a cooling fan has the drawback, however, that not only cooling air is supplied to the front panel, or the screen, of the cathode ray tube, but also dust particles which adhere to the front panel and have an adverse effect on the achievable image clarity. Furthermore, such a cooling fan usually does not operate silently.

In connection therewith, liquid cooling of the display has been started, in which a transparent, liquid coolant, more in particular a liquid with considerable heat convex properties, is used for cooling the front panel of the cathode ray tube.

In the case of the use of three such cathode-ray tubes for forming separate or associated color images on a projection screen, it is desirable for the mounting of the respective color projection device, 8201929 -—----- - W - »I t - 3 - that the image color of the respective cathode ray tubes is easily identifiable. However, since the cathode ray tubes of different colors not only have the same shape, but also have the same screen color (almost white) when not in use, identification of the color of a cathode ray tube is difficult, as is the determination whether such a cathode ray tube is already of the desired refrigerant is provided.

Furthermore, in order to obtain a projected color image of high fidelity, it is desirable that the color tone or shade of the obtained image can move within a wide range. To this end, the colorimetric purity of the individual color images formed by the respective cathode ray tubes must be as great as possible. In particular, this applies to the cathode ray tube serving to form a green color image; in particular, it should have the highest possible color purity.

The object of the present invention is to provide this and to provide a cathode ray tube with a liquid-cooled display or a device equipped with one or more such cathode ray tubes, which is free of the drawbacks described above of existing cathode ray tubes of this type.

Another object of the invention is to provide a cathode-ray tube with a liquid-cooled display or a device equipped with one or more such cathode-ray tubes, wherein the cooling of the display or the color phosphor layer can be obtained in an efficient manner and with the time-changing property changes are minimized to extend the useful life.

Another object of the invention is to provide a cathode ray tube with a liquid-cooled display, whereby immediate identification of the image color is possible.

8201929 - 4 -

Yet another object of the invention is to provide a cathode ray tube with a liquid-cooled display wherein the presence or absence of coolant can be determined.

Yet another object of the invention is to provide a cathode ray tube with a liquid-cooled display, with which a considerable colorimetric purity can be achieved.

To this end, the invention is based on a cathode-10 jet tube, which is provided with: a) a housing with a front panel provided with a phosphor layer on its inner surface, a neck part with an electron gun inside, and a projection extending between the front panel and the neck part, funnel-shaped section; b) a transparent panel disposed opposite the outer surface of the front panel and separated by a spacer therefrom, and c) a transparent coolant sealed between the front panel and the transparent panel.

For such a cathode ray tube, the invention now prescribes that the cooling liquid exhibits such properties or contains such a substance that absorption of through light emitted by the phosphor layer of wavelengths other than within a range extending around the main wavelength is obtained.

In addition, starting from a device, which is equipped with: a) a number of cathode-ray tubes with one or more associated lens systems, the cathode-ray tubes each containing a front panel provided with a phosphor layer on its inner surface, b) an opposite surface of the front panel, transparent panel, and with 35 c) a transparent coolant sealed between the front panel and the transparent panel, the main emission wavelengths of the phosphor layers 8201929 r »* - 5 - of the front panels of at least two of the cathode ray tubes differing from each other the invention further prescribes that in the cooling liquid of at least one of the two cathode-ray tubes mentioned above, a dye has been dissolved, the color of which corresponds to the main emission wavelength of the phosphor layer of the front panel of the relevant cathode-ray tube.

The invention will be elucidated in the following description with reference to the accompanying drawing of some embodiments, to which the invention is not, however, limited. In the drawing: Fig. 1 shows a schematic representation of a color image projector with three cathode-ray tubes with liquid-cooled screen according to the invention, Figs. 2 and 3 show a front view and a partly sectioned side view of an embodiment of a cathode ray tube with liquid-cooled display according to the invention, Fig. 4 is a graph showing the freezing point of an aqueous ethylene glycol solution, Fig. 5 is a graph showing the transmittance of a cooling liquid with a dye dye dissolved therein wavelengths, Fig. 6 and 7 show optical spectral distributions of a color phosphor and a coolant, and Fig. 8 a so-called "color triangle".

In an embodiment of a cathode-ray tube according to the invention, which is, for example, carried out according to Figs. 2 and 3, which can serve as one of the picture tubes R, G and B of the device according to Fig. 1, an optically transparent front is located. panel 2, which is for instance made of glass. This transparent panel 2 extends opposite and some distance from the outer surface of the front panel 1a of the envelope 1 of the cathode ray tube and is kept at a distance from said front panel 1a by an annular spacer 3, 8201929-6 - which extends the peripheral parts of both panels 1a and 2a extend. These spacers 3, which have a flange-shaped projection 3a with a rearwardly converted part 3b, are sealingly received between the two panels along the peripheral parts or edges of the two panels 1a and 2. In the embodiment of a cathode ray tube according to the invention shown in Figs. 2 and 3, at the converted protrusion portion 3b, in the radial direction, a number of securing protrusions 4 protrude, which serve to fix the cathode ray tube to a fixed member, such as a box, a chassis or the like and are provided with respective mounting holes 5 for this purpose. Between the flange-shaped projection 3a of the spacer 3 on the one hand and the two panels 1a and 2 on the other hand, the spacer 3 consists of two respective sealing rings 6 and 6 ', which are for instance made of silicone rubber and are embedded all around in an adhesive mass 7 , which is, for example, on a silicone basis or the like and complements the sealing action of the spacer 3 with respect to the peripheral parts of the two panels 1a and 2 to form a good liquid-resistant seal, such that a sealingly closed space 8 is provided between the two panels remains. The cooling liquid is injected into this closed space 8 via a small opening, not shown in the drawing, in the flange-shaped protrusion 3a, after which the above-mentioned small opening is closed and the cooling liquid is sealed in the closed space 8.

During operation, such a cathode ray tube is usually in such a position that the casing panel 1a extends along an at least substantially vertical plane.

The cooling liquid 9 enclosed in the closed space 8 is in contact with the front panel 1a of the cathode ray tube housing 1 and with the transparent panel 2.

With a temperature rise of the front panel 1a of the cathode ray tube, the cooling liquid 9 heated thereby will move upwards within the closed space 8, or will itself generate heat convexion, 8201929 P --- "*.-7-, whereby the heart heating occurring from the front panel 1a are efficiently vented to the peripheral portions of the panel. If the spacer 3, which extends along the peripheral portion of the front panel 1a 5, is made of a metal with high thermal conductivity, such as, for example, aluminum, and if the surface of the spacer exposed to the ambient air has been surface-treated such that has a relatively large thermal radiation coefficient, respectively a relatively large heat radiation effect, the heat dissipated in the manner described above by liquid convexion to the peripheral part can be very efficiently dissipated through the spacer 3, so that an improved heat dissipation is obtained from the center of the front panel 1a of the cathode ray tube. As a result, it can be in continuous operation for a long period of time and a considerable life of the cathode ray tube is obtained.

The cooling liquid 9 enclosed within the closed space 8 must have the following properties: the cooling liquid must not only exhibit a considerable heat convexion and a high thermal conductivity, but must also - in view of the requirement that the cathode ray tube be kept at temperatures * - 20 ° C must be able to function -25 have a freezing point lower than - 20 ° C and moreover have a boiling point higher than + 100 ° C, since the cathode-ray tube temperature approaches the latter temperature value during operation. Namely, if boiling phenomena occur in the cooling liquid, for example as a result of the use of a cooling liquid with a boiling point too low for normal use of the cathode ray tube, then there is a danger that the space 8 between the two panels is closed. 1a and 2 prevailing fluid pressure rapidly increases, from which damage to the fluid seal and cooling fluid may already leak in the first instance.

According to the invention, the coolant 9 8201929 exists

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- δ - from an aqueous ethylene glycol solution containing 35-95% by weight and preferably 40-90% by weight of ethylene glycol. For the use of cathode ray tubes of different colors, such as the cathode ray tubes R, G and B used in the device according to Fig. 1 for the colors red, green and blue, respectively, in the cooling liquid 9 one becomes for absorbing light of wavelengths other than the main wavelength range and light located in unnecessary wavelength ranges, respectively, are solved? thereby the cooling liquids 9 of the different cathode ray tubes have the effect of color filters.

The amount of dye to be added is greater than 0.5 ppm and less than 1000 ppm, 1000 ppm representing the saturation limit of the solution. If the amount of dye added remains below this limit, it has no influence on the physical properties of the cooling liquid 9, such as the freezing point, the look point, the viscosity and the like.

Fig. 4 is a graph showing the relationship between the concentration of ethylene glycol in the coolant and its freezing point. At a concentration between 35 and 95% by weight, the freezing point appears to be below -20 ° C, which is necessary for use as a cooling liquid with a cathode ray tube, as has already been noted.

As also already noted, a cathode ray tube with a liquid-cooled display according to the invention, wherein the cooling liquid is formed by an aqueous ethylene glycol solution with 35-95 wt.% And preferably 40-90 wt.% Ethylene glycol, meets many requirements. Thus, in such a cooling liquid 9, a very effective heat convex is obtained, while the cooling liquid has a high thermal conductivity, so that a local temperature rise of the front panel 1a of the cathode-ray envelope 1 is avoided and the heat generated is radiated effectively. Furthermore, this coolant has a freezing point below -20 ° C and a boiling point above + 100 ° C? these properties are associated with high optical transmittance, while the 8201929 F-- i * - 9 coolant is low cost and non-toxic. This makes handling of the cathode ray tube easy and risk-free, while manufacturing is relatively simple.

The following is noted with regard to the dyes to be dissolved in the cooling liquid according to the invention. With a cathode ray tube for the color green, both methyl orange and brilliant blue can be used side by side; for a cathode ray tube for the color blue, brilliant blue can be used, and for a cathode ray tube for the color red, neutral red or rhodamine B can be used.

However, the potentially eligible dyes are not limited to these examples.

As already noted in the foregoing, the cooling liquids used according to the invention are also used as filter elements for the respective colors of the cathode ray tubes. If a cooling liquid with methyl orange and brilliant blue is used in the cathode ray tube serving to form the green color image, which green color image has a very high brightness factor, the green color image transmitted through the cooling liquid obtains a high colorimetric purity.

Fig. 5 is a graph showing the optical transmittance of the aforementioned aqueous ethylene glycol solutions with the respective dyes dissolved therein. The optical transmittance is always plotted as a function of the wavelength of the light. Curves 31, 32, 33 and 34, drawn in full line, represent the measurement results for the respective cases where 2 ppm, 5 ppm, 10 ppm and 20 ppm brilliant blue is dissolved in the coolant 30. Curves 41, 42, 43 and 44, drawn in broken lines, show the measurement results for those cases where 2 ppm, 5 ppm, 10 ppm and 20 ppm of methyl orange are dissolved in the coolant, respectively, while the measurement curves 51, dotted and dashed, 52, 53 and 54 refer to 35 cases in which 2 ppm, 5 ppm, 10 ppm and 20 ppm of neutral red are dissolved in the coolant, respectively.

When brilliant blue is dissolved together with methyl orange in 8201929 - 10 - * τ, the cathode ray tube serving to form the green color image creates the desired combination of filter properties according to curves 31-34 and 41-44.

For example, in the cathode ray tube intended for forming the green color image, where Gd202S: Tb with the luminosity properties according to Fig. 6 is used as the color phosphor, an aqueous ethylene glycol solution in which brilliant blue 10 and methyl orange are each dissolved at 20 ppm is selected as the cooling liquid, For such a cooling liquid according to the invention, the transmittance properties according to Fig. 7 are obtained, which show that light with a wavelength within the range of about 540-550 nm is transmitted, but light of wavelengths outside the range just mentioned is largely transmitted. is filtered out. It will be clear that the green color image emitted by means of a cathode ray tube with such a cooling liquid according to the invention has a very high colorimetric purity.

In the case of the cathode ray tubes serving to form a red color image and a blue color image respectively, it also holds that by correct selection of the dyes to be dissolved in the cooling liquid used, an improved color purity can be obtained.

FIG. 8 shows a so-called "color triangle" based on xy coordinates according to the proposal made in 1931 by the CIE (Commission Internationale d'Eclairage '; ICI, International Commission on Illumination) for the combination of three cathode ray tubes with respective red, 30 green and blue color f os large screens of Y20g: Eu, Gd ^^ ïT ^ and ZnS: Ag. For such a combination, points r, g and b in Fig. 8 determine the triangular area enclosed by the drawn line a, within which all color types which can be reached with such a combination lie, that is to say, without using the filter proposed by the invention. operation. If in the coolant 9 for the cathode ray tube brilliant blue added to the image color green, 8201929 s * lien methyl orange, each amounting to 20 ppm, are dissolved, the point g in fig.

8 moved to point g '. When neutral red in the amount of 20 ppm is dissolved in the cooling liquid 9 for the cathode ray tube 5 added to the image color red, the point r in fig. 8 shifts to r1 for the transmitted light. As a result, the triangular region of possible color types surrounded by the broken line a 'in Fig. 8 appears to be considerably expanded from the original region surrounded by the solid line a. This means that the range of possible color types has been broadened and better color fidelity is obtained.

The addition of dyes proposed by the invention in the cooling liquids used in the cathode ray tubes also provides the possibility of directly identifying the image color for which a cathode ray tube is intended, that is to say also when it is not in operation. Moreover, the proposal provides the possibility of directly determining whether the relevant cooling liquid is already enclosed in the space 8 of a cathode ray tube. These aspects facilitate storage, handling and mounting of the respective cathode ray tubes prior to operation. To investigate the cooling effect of the coolant proposed by the invention, the following test was conducted, starting with a cathode ray tube of monochromatic type and a display screen of the "5.5 inch" type, in which very high image clarity was produced using an excessively high electron beam current; the distance between the two panels 1a and 2 was approximately 5mm and the thickness of the two panels 6mm? the amount of coolant 9 enclosed within the closed space 8 was about 55 cm.

The heating test was carried out such that four cathode ray tubes of the just described were prepared such that two pieces were equipped with an 8201929 - 12 - aqueous ethylene glycol solution containing 50% by weight ethylene glycol as coolant 9 and two pieces were equipped with an aqueous ethylene glycol solution containing 80% by weight ethylene glycol as coolant 9. First, the cathode ray tubes thus prepared were placed in an environment of -40 ° C for three hours. Neither freezing nor leakage of the coolant occurred. The cathode ray tubes were then heated to 120 ° C in a liquid bath, creating three different test conditions.

Under the first conditions, the cathode ray tubes were kept in a constant temperature bath of 120 ° C for two hours, under the second conditions, the cathode ray tubes were further heated to 130 ° C and held in a constant temperature bath of 130 ° C for two hours and under the third conditions, the cathode ray tubes were further heated to 140 ° C and held in a constant temperature bath of 140 ° C for two hours. Under the first conditions, none of the cathode ray tubes experienced fluid leakage or the like. Under the second conditions, excellent results were obtained for the cathode ray tubes with a cooling liquid consisting of an aqueous ethylene glycol solution with 80% by weight of ethylene glycol and for the cathode ray tubes with a cooling agent consisting of such a solution with 50% by weight of ethylene glycol. samples obtained excellent results. Under the third conditions, excellent results were obtained for half the number of samples for the cathode ray tubes with a cooling liquid consisting of an aqueous ethylene glycol solution containing 80% by weight ethylene glycol. The table below shows the thermal expansion coefficient CA for different weight percentages of the aqueous ethylene glycol solution. and the boiling point under the various aforementioned conditions.

OO wt% ethylene glycol oC. boiling point 0 2.1 x 10 “4 100 50 3.9 x 10 ~ 4 107 tO 80 5.0 x 10 ~ 4 125 100 5.7 x 10” 4 198 - 13 - ΐ J *%

From the foregoing it appears that a cathode-ray tube with a liquid-cooled display according to the invention, or a device equipped with one or more such cathode-ray tubes, provides excellent heat dissipation within a wide range of 5 temperatures. Such a cathode ray tube or device can function for a long period of time and has a considerable service life.

The concentration of the dye in the coolant can be selected within a range of 0.5 ppm - 1000 ppm. In view of the brightness reduction occurring in the proposed filtering operation, it is recommended that for the concentration of the dye added to the cooling liquid for the cathode ray tube 15 added to the image color green, a value of less than 100 ppm or even less than 50 ppm is chosen? the respective cathode ray tube has a high light output factor.

The invention is not limited to the embodiment described above? various modifications can be made in the details described and in their mutual connection, without thereby exceeding the scope of the invention.

8201929

Claims (4)

1. A cathode ray tube, comprising: a) a casing having a front panel provided with a phosphor layer on its inner surface, a neck section with an electron gun inside, and a funnel-shaped section extending between the front panel and the neck section; b) a transparent panel disposed opposite the outer surface of the front panel and separated by a spacer therefrom, and c) a transparent coolant sealed sealingly between the front panel and the transparent panel, characterized in that the coolant has such properties. or contains such a material that absorption of transmitted light emitted by the phosphor layer of wavelengths other than within a range extending around the main wavelength is obtained. Cathode ray tube according to claim 1, characterized in that the cooling liquid is formed by an aqueous solution in which a dye for absorption of light of wavelengths other than within the main wavelength range is dissolved. Cathode ray tube according to claim 2, characterized in that the dye has a concentration within the range of 0.5-1000 ppm. 25 4. Device, equipped with: a) a number of cathode ray tubes with one or more associated lens systems, the cathode ray tubes each comprising a front panel provided with a phosphor layer on its inner surface, b) a transparent panel arranged opposite the outer surface of the front panel, and c) a transparent coolant sealed between the front panel and the transparent panel, the major emission wavelengths of the phosphor layers 35 of the front panels of at least two of the cathode ray tubes differing from each other, characterized in that a dye has been dissolved in the cooling liquid of at least one of the two cathode-ray tubes mentioned, the color of which corresponds to the main emission wavelength of the phosphor layer of the front panel of the relevant cathode-ray tube. 8201929