NL8302119A - LIQUID COOLED CATHODE JET TUBE. - Google Patents

Description

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Cathodes.traal tube of the liquid-cooled type.

The invention relates to a cathode-ray tube of the liquid-cooled type, and more particularly to such a cathode ray tube with high image brightness for use in color image projection devices.

Such a cathode ray tube of the high image brightness operating type is generally driven such that the energy of the electron beam directed at the phosphor screen of the tube is very high, so that a very considerable image brightness is obtained on the screen. In addition, the amount of heat generated when the electron beam of the cathode ray tube strikes the phosphor screen, and / or the amount of heat generated when one or more electron beams is disposed within the envelope of the cathode ray tube for determination of the position of the beam spot on the screen, such as a shadow mask, a grid with apertures or the like, due to the very high energy of the electron beam 20 used, are very considerable. Since the front panel of the tube envelope of the cathode-ray tube, which is usually made of glass and carries the said phosphor screen, itself has a relatively low thermal conductivity, which is the case, especially with uninterrupted use of such a cathode-ray tube, in the center of the front panel where heat radiation is difficult, a significant temperature rise may occur, from which so-called "thermal quencing" of the phosphor screen may result. As a result of the phenomenon just mentioned, the image brightness of the phosphor screen decreases as the screen temperature increases. Since the extent to which the thermal quenching phenomenon occurs is not always the same for the phosphors of different colors, the white balance of the color image formed is disturbed.

- 35 Since such a white balance distortion in the center of the front panel is a significant 8302119 -2-s-r. It has already been considered to individually adjust the image brightness for the various partial colors of the image, and in this way, with continued use of a picture tube, to obtain a correct white balance in the center of the image. front panel. However, such a measure results in the white balance on the outer periphery of the front panel being lost, while also the total image brightness cannot be increased.

These undesirable phenomena also occur, for example, with a color image projection device, wherein the color images for the different partial colors are supplied by separate, monochromatic cathode-ray tubes, are then mixed together and to obtain a composite color image on a screen. projected.

In the case of a cathode ray tube of the high image clarity type, cooling of the front panel of the cathode ray tube should be used to avoid temperature rise caused by continuous use, which could cause said thermal quenching. Such cooling of the front panel can be carried out with the aid of a cooling fan. Thereby, however, not only cooling air is blown onto the outer surface of the front panel of the cathode ray tube, but also dust which adheres to the front panel and adversely affects the achievable image clarity. The use of a cooling fan also has the disadvantage that it does not operate silently.

In connection with the foregoing, use has already been made of the use of a transparent cooling liquid, which has good heat convection properties and is contacted therewith for cooling the front panel of a cathode ray tube.

FIG. 1 of the accompanying drawing.

a side view, partially in section, through such a cathode ray tube of the previously proposed type with liquid cooling. The cathode ray tube is provided with an envelope 1 with a front panel 1a, for which a transparent panel 2, for example of glass, with good optical transmission is arranged, while an annular body 3 of metal with very good thermal conductivity properties as a spacer along the circumferential edges of the two panels 1a and 2 are inserted between the two panels. The outer peripheral parts of the metal body 3, the outer surface of the front panel 1a and the inner surface of the transparent panel 2 are liquid-tightly connected to each other by means of an adhesive 4 of synthetic resin, so that between the two panels 1a and 2 a liquid-tight space 5 results; within this space is a transparent coolant 15 6 with good heat convection properties. In FIG. 1, reference numeral 7 refers to a phosphor screen formed on the inner surface of the front panel 1a.

A cathode ray tube of the type shown in FIG. 1 is usually used in a position in which the front panel 20a extends at least substantially in a vertical plane.

The cooling liquid 6 within the space 5 is in close contact with the front panel 1a. When a temperature rise occurs in the latter, the coolant 6 heated thereby will move upwards, resulting in convection inside the space 5 filled with coolant. In such an arrangement, heat which develops in the central portion or center of the front panel 1a is also effectively dissipated to the outer peripheral portion of the front panel and then delivered to the annular body 3, which is made of a metal with good heat conduction properties, such as aluminum. As a result, the heat generated in the front panel 1a is first transferred to the metal annular body 3 and then radiated by the latter into the surrounding air.

In a device, such as a color image projection device 830 2 1 1 9 t 1 4 »-4, which has a position as shown in FIG. 1 cathode ray tube is equipped, an effective elimination of undesired temperature increases from the front panel 1a of the cathode ray tube is possible.

For some time, however, the requirements imposed on such projection devices have been increasing. The projection device should have both a high image brightness and a high image resolution, and moreover a considerable power, from which an ever increasing heat development results. When increasing the acceleration voltage applied in the cathode ray tube, for example to increase the tube power (this power P can be expressed as P = V. Iv, P £ in which the anode or acceleration voltage is and 1 ^ is the cathode current), in addition, the thickness of the front panel 1a of the envelope 1 of the cathode ray tube should be increased to avoid the increase of X-ray radiation. When a plastic lens is used as an optical system in such a projection device, the distance 20 between the phosphor screen 7 and the lens in question, i.e. the thickness of the front panel 1a, cannot be increased indefinitely, however, due to the design of the lens. turn into.

In connection therewith, when using a transparent panel 2 of glass, it has already been proposed to increase the lead content of the glass, so that the undesired X-ray radiation is better shielded. Glass with a relatively high percentage of lead, as mentioned above, however, shows a reduced hardness and is moreover sensitive to scratches. When a temperature rise occurs, as described above, such deformation (bending due to thermal expansion) of the transparent panel 2 can occur that the panel breaks. In connection therewith, the requirement of greater or increased image clarity should be matched with more effective cooling by heat radiation.

In connection with this, in a cathode-ray tube of the type shown in FIG. 1 working, known 8302 1 1 9

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(-5- * * device already used a heat radiation fin for enlarging the active air cooling surface of the metal body 3. However, it does not appear that a sufficiently effective heat radiation is obtained. Experiment-5 has shown that in such a case Insufficient heat transfer from the cooling liquid 6 to the annular body 3 occurs as a result of the fact that the annular body 3 is connected to the two panels 2 and 1a 10 in a liquid-tight manner by means of the adhesive 4 of synthetic resin. surface area over which the annular body 3 comes into contact with the cooling liquid 6 is very limited, so that no effective heat transfer from the cooling liquid 6 to the annular body 3 is obtained.

The object of the invention is to improve on this and to provide a cathode ray tube of the type considered here, which is free from the above-mentioned drawbacks.

Another object of the invention is to provide a cathode ray tube of the high image clarity type, without any risk of thermal quenching.

Another object of the invention is to provide a cathode ray tube of the high image clarity type, which combines high power with high image resolution during operation.

Yet another object of the invention is to provide a cathode ray tube of the high image clarity type, whereby a very effective heat radiation and liquid cooling is obtained.

Yet another object of the invention is to provide a cathode ray tube of the high image clarity type, wherein an effective heat transfer of the cooling liquid used is obtained to a metal body surrounding the effective display of the tube.

Yet another object of the invention is to provide a cathode ray tube of the large 8302 1 1 9 I 1

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-6- image brightness operating type, which is particularly suitable for use with color image projection devices.

Starting from a liquid-cooled type cathode ray tube with a flat front panel, which bears a layer serving as a phosphor screen and is surrounded by a metal radiant heater and a spacer, the flat radiant panel being some distance from the flat front panel by the metal radiant heater is supported, while the two flat panels and the radiant heater are fluidly sealed together to form a chamber containing a transparent refrigerant with a cooling fin added to the metal radiant heater, invention, for the cooling fin to protrude inwardly on the inner wall of the radiant heater 15.

The invention will be elucidated in the following description with reference to the accompanying drawing of an exemplary embodiment, to which, however, the invention is not limited. Show in the drawing; FIG. 1 is a side view, partly in vertical section, on a cathode ray tube of known liquid-cooled type,

Fig. 2 a similar side view, largely in vertical section, on a cathode ray tube of liquid-cooled type according to the invention,

Fig. 3 a front view. the metal cooling body of the cathode ray tube according to FIG. 2,

Fig. 4 is a side view of the heat sink according to FIG. 3, 30. 5 shows a section along line A-A

Fig. 3 and

Fig. 6 is a graph for explaining the effect obtained in applying the invention.

In the case shown in FIG. 2 embodiment 35 of a liquid-cooled type cathode ray tube according to the invention, an annular body 10 of metal is disposed around the actual display of the cathode 8302119 * (* tk -7) nozzle formed by the outer surface of the front panel 1a, which bears the phosphor screen 7 on its inner surface. Opposite the front panel 1a and at a predetermined distance therefor is a transparent panel 11, which is made of glass plate 5, and which is held in that position by the metal body and enclosing a liquid-tight space 12 with the front panel 1a. The metal body 10, which will be described in further detail, is fluid-tightly connected to the transparent panel 11 and the front panel 1a by means of an adhesive 13 of plastic such as silicone resin or the like, so that the body 10 and the transparent panel 11 are mechanically connected to the front panel 1a.

Within the liquid-tight space 12 between the two panels 11 and 1a is a cooling liquid 13 *, for example a water solution of ethylene glycol.

Pig. 3 shows a front view of the metal heat sink 10, of which FIG. 4 is a side view and FIG. 5 is a cross-section along the line A-A in FIG. 3 shows. The metal heat sink 10 is made of a material with excellent heat conductivity properties, such as aluminum cast in a casting process, and is incorporated as a spacer between the outer edge portions of the two panels 1a and 11 of the casing 1 of the cathode-ray tube. The distance between the two panels desired for the space 12 is maintained with the adhesive 13 of plastic. The body 10 has a substantially flat-frame-shaped portion 1a, 30 connecting to its outer edge into an axially annular portion 10b extending along the outer circumferential edge 1a of the front panel 1a of the envelope 1 of the cathode-ray tube. the front panel and of the envelope 1 locally extend and in turn, along the two opposite sides of the portion 10b, turns into flange-shaped portions 35 10c, which extend radially outwardly * and from for mounting the cathode ray tube 1 in a Holes 14 provided for cabinet or panel are provided. In addition, the flange-shaped portions 10c have a number of mutually parallel cooling fins 10 perpendicular to the portion 10c on their outer sides.

As disclosed in the invention, 5 is located on the inner edge of the molded body portion 10a, which extends as a spacer between the transparent panel 11 and the front panel 1a of the cathode ray tube, that is, on the inside of the plastic adhesive 13 ' portion of the body 10 connected to the two panels 11 and 1a 10, a fin-shaped cooling projection 10e extending radially inwardly along the entire inner circumferential length of the strip-like portion 10a. This fin-shaped, inward cooling projection 10e is positioned so that it is not covered by the synthetic resin adhesive 13 during the manufacture of the cathode ray tube. The side walls of this fin-shaped, inward cooling projection 10e face the respective panels 11 and 1a, while the cooling projection 10e is almost completely surrounded by the cooling liquid 13 'and participates in the heat exchange with the cooling liquid 13'. The cooling protrusion 10e, as already noted, extends over the entire inner peripheral edge of the molding portion 10a. In the embodiment described here, however, the cooling projection 10e has two cut-out portions 10 or 25 (see Fig. 3), into which respective channels 15 (see Fig. 4) open for supplying the coolant 13 'to the aforementioned space 12. The cut-out portions lOr the only interruptions of the cooling projection are 10e.

As Fig. 3, the inner cooling projection 10e remains outside the outer edge of the effective display indicated by the letter a. Nevertheless, in order to prevent light from the phosphor screen 7 from reflecting to the cooling protrusion 10e of the cooling body 10 and interfering with a visualized image, the surface of the cooling protrusion 10e has been at least partially blackened. Such a sweat should preferably be applied to the entire surface of the metal body 8302119% -9-t, thereby improving the heat radiation and absorption of the heat transferred by the cooling liquid 13 '. When the metal heatsink 10 is made of aluminum, the blackening can be performed by almietbghanrfc »! ing, and further optionally by means of a dye. When the outer surface of the% metal heatsink is electrically insulated as a result of such blackening, the blackening should be removed in the place or places where the observation of an image visualized on the screen cannot be reflected by light reflecting on the heatsink 10 are disturbed; at such locations, the cooling liquid 13 'and the metal body 10 are then galvanically connected to each other. Since the transparent cooling liquid 13 ', such as glycol, etc., has a certain electrical conductivity, the panels 11 and 1a can for instance be earthed via the cooling liquid 13' and the metal heat sink 10, so that both panels are not charged statically. As synthetic resin adhesive 13, for example, a black pigment sylicon resin can be used. In order to ensure that the silicone resin, which together with the frame-shaped part 10a of the heat sink 10 serves as a spacer between the transparent panel 11 and the front panel 1a, has a certain thickness, if desired, hardened granular or elastic plastic particles 25 with a certain thickness are added to the adhesive 13.

In the above described embodiment of the invention, it has been found that an improved heat radiation was obtained, such that the power of the cathode ray tube could be increased by 30% compared to a cathode ray tube of conventional type with liquid cooling. Fig. 6 shows the temperature rise at the surface of a cathode ray tube as a function of the cathode current I, when an anode voltage V of jc p 27kV is applied to the phosphor screen 7 of the tube. The curve 16 in 35 FIG. 6 shows the respective temperature trend in a liquid-cooled cathode ray tube according to the invention.

Comparison with the curve 17, which shows the measurement results for a liquid-cooled cathode-ray tube of the usual type, the metal heat sink 10 of which does not have an inwardly projecting cooling section 10e surrounded by the cooling liquid, clearly shows the reached 5 result. At the same cathode current strength and the same power, a considerably lower temperature rise of the screen is obtained with a cathode ray tube according to the invention. The result of this is that a higher power can be used with a cathode-ray tube according to the invention under otherwise identical conditions or for the same temperature behavior.

The following table contains some measured values, which represent the average temperature of the coolant in the state in which the temperature prevailing on the surface of the cathode ray tube has reached its equilibrium state. These measured values relate to three comparative examples 1,2 and 3 of a liquid-cooled cathode ray tube of known type according to fig. 1 and four examples 1, 2, 3 and 4 of a liquid-cooled cathode-ray tube according to the invention, in which continuous operation was used at an anode voltage V of 26 kV and a cathode current of 43 (J / nA. In the table, the heat radiation area , which is in contact with the air, and the heat absorption surface, which is in contact with the cooling liquid, for the examples (invention) is always relative to the respective surfaces of the comparative example 1 (known), which as respective units In Examples 1-4, the thickness of the frame-shaped portion 10a of the metal heat sink 10 is chosen to be 3.8mm, while the thickness of the cooling projection 10e is chosen to be 1mm. 1 and 2, for the length over which the cooling projection 10e extends inwardly, a value of 3 mm is chosen; for examples 3 and 4, this value is 5 m m selected.

* 8302119 9.

-11- * ft heat radiation heat absorption average surface area temperature ____cr_ comparison. , 1 1 30 example 1 5 comparison, _ 2 1 27 example 2 comparison example 36 1 24 example 1 2 2 23.5 10 example 2 x 3/3 27.5 example 3 2 3 <3 23 example 4 6 23 17

As appears from the table, the invention provides the possibility of obtaining an improvement in the heat dissipation by increasing the heat radiation surface such that a temperature rise of the cooling liquid due to an increased power is prevented.

As described above, the application proposed by the invention of an inwardly cooling protrusion 10e with the cooling liquid 131 in heat exchange fluid leads to the metal body 10, which extends between the transparent panel 11 and the front panel 1a of the cathode ray tube. , to a significant improvement in heat dissipation, such that "the power of the cathode ray tube can become considerable." ι> staged. As already described, more particularly when using such a liquid cooled type cathode ray tube in a color image projection apparatus it is possible to prevent thermal quenching from occurring; this makes it possible to obtain a color image without disturbing the white balance, that is to say a very color-pure and clear color image.

Due to the blackening of the metal heat sink 10 ,. and more particularly of its inward cooling protrusion 10e at the places where it could be observable from the front, the contrast of a visualized color image can be improved and there is no danger of deteriorating the image quality by reflecting unwanted light affected.

The invention is not limited to the embodiment described above and shown in the drawing. Various changes can be made in the details described and in their interrelationships, without exceeding the scope of the invention.

8302119

Claims (3)

1. A liquid-cooled type cathode-ray tube with a flat front panel, which bears a layer serving as a phosphor screen and is surrounded by a metal heat radiator and a spacer, the flat metal panel being at a distance from the 5 heat radiator. the flat front panel is supported, while the two flat panels and the radiant heater are connected to each other in a liquid-sealing manner by means of a covering means, forming a chamber within which a transparent coolant is located, wherein a cooling fin is added to the metal radiant heater characterized in that the cooling fin protrudes inwardly on the inner wall of the radiant heater. Cathode-ray tube according to Claim 1, 15, characterized in that the thickness of the cooling fin is smaller than that of the radiant heater. Cathode ray tube according to claim 1 or 2, characterized in that the cooling fin is at least partially blacked. 8302119