DE1932172A1 - Cooling device - Google Patents

Description

Sony Corporation, Tokyo / Japan

Cooling device

The invention relates to a cooling device for mercury arc lamps or the like, in particular on a device for water cooling a linear light source.

Light sources of high brightness are required for the manufacture of color picture tubes. Mercury arc lamps are widely used for this purpose; you need however, a cooling device if high brightness is desired. The cooling generally takes place either by air cooling or by water cooling. The water cooling is very effective, but it throws in terms of the Construction of the cooling device has certain problems, also leads to difficulties in changing the light source as well as unevenness in light intensity; the latter is due to air bubbles in the cooling water that are on Place the surface of the mercury arc lamp and a glass window of the cooling water tank. As the cooling water heats up, the generation of such gas bubbles is inevitable.

The cooling device also requires a window, for example made of glass, which opens the mercury arc lamp lets through emitted light. At this window there is a total reflection of the light, which means a loss of light brings with it. Furthermore, there the light one after the other

0008 2a / 132S

passes through water, glass and air that have a different Have refractive index, there is a virtual displacement of the light source.

The invention is therefore based on the object of avoiding these shortcomings of the known designs Train the cooling device so that the flow rate of the cooling water in the area in which no gas bubbles should be present, is enlarged.

The invention is essentially characterized in that a housing with an inlet line for the introduction of cooling water, a light source and an outlet line for discharging the cooling water from the housing are provided, and that there is also a line connected to the outlet line and containing the light source is, furthermore a transparent window through which the light radiation of the light source falls to the outside, and that finally there is a nozzle which is connected to the inlet line and which directs a jet of cooling water into the vicinity of the window.

The cooling water emerging from the nozzle consequently flows along the window part and removes all air bubbles present in the cooling water from the window.

The cooling device according to the invention is consequently characterized by a very uniform light intensity. It is also advantageous that the light source can be exchanged without difficulty. Furthermore, light losses and a shift in the effective position of the light source are avoided.

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An embodiment of the invention is shown in the drawing illustrated. Show it

1 is a diagram for explaining the optical printing of a parbosphorus screen;

2 shows a schematic illustration of a known cooling device of a mercury arc lamp;

3 shows a partially sectioned plan view of a cooling device according to the invention;

FIG. K shows a side view of the cooling device according to FIG. 3;

FIGS. 5 and 6 are sections along the lines V-V and VI-VI of FIG. 3.

For color picture tubes of the Chromatron or Trinitron system is a grid arrangement, which consists of a plurality of parallel grid elements, for example metal wires or in a Direction is stretched at predetermined intervals strips, arranged opposite the color phosphor screen. One on the Phosphorus screen directed through the grid elements electron beam hits the screen at predetermined points, which one correspond to a certain color.

The phosphor screen of the color picture tube of this version is made from a number of phosphor strips, each emitting red, green and blue light and successively in one recurring cyclical order arranged in a direction that is your lengthways direction at a right angle crosses.

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To produce such a phosphor screen consisting of the phosphor strips explained, a Optical printing process used, these phosphor layers successively using an optical mask or a lattice having a predetermined pattern can be applied as a coating.

This optical printing method is briefly explained with reference to FIG. A phosphor sludge 2, for example from a Red color-emitting phosphor and a photosensitive binder mixed together is applied to the whole inner surface of the window 1 of the tube jacket of a color picture tube applied if a color phosphor screen is on this inner surface should be generated. An optical mask 3, the optical pattern of which corresponds to the finally generated pattern of the mentioned corresponds to the red phosphor stripe of the color phosphor screen, is arranged opposite the window 1. Behind the optical Mask 3, a light source 4 is provided.

Then, the phosphor sludge 2 applied to the inner surface of the window 1 is passed through the optical mask 3 Light from the light source 4 is exposed so that a latent image of the optical pattern of the mask 3 is formed in the mud forms. Thereafter, the inner surface of the window 1 is subjected to a development process, so that red-colored Form phosphor strips of a predetermined pattern. These processes are carried out in the same way with phosphors of other colors, for example with green color and blue color emitting Phosphor, repeated until a complete phosphor screen is created on window 1.

In this case, the light source 4 is usually a mercury arc lamp. The light source k should preferably be a linear light source that extends in the longitudinal direction

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of the phosphor strips eventually formed extends so that uniform exposure of the phosphor strips and thus their luminosity is achieved over their entire length.

A mercury arc lamp with a linear luminous part and high brightness naturally has a small tube diameter, which increases the heating value per unit area of the tube surface and is therefore an effective one Requires heat radiation from the tube surface. The water cooling process is believed to be an effective heat dissipation. However, air is always contained in the cooling water and creates bubbles on the surface of the mercury arc lamp or rest on the window glass of a lighting window of the cooling device. Since the air in the Cooling water expands by the heat of the mercury arc larape, the bubbles grow together and become larger. if accordingly, the bubbles rest on the surface of the mercury arc lamp, will not be effective in the area of the bubbles Cooling of the lamp surface achieved; the heat radiation is interrupted by the air in the bubbles. Consequently the heat generated by the mercury arc lamp is not effectively radiated; the lamp tube is turned on locally heated to a high temperature, which leads to stress in the tube and ultimately to explosion. If furthermore the bubbles lie on the glass window which lets the light of the mercury arc lamp through to the outside, so the lamp light becomes broken by the bubbles, resulting in unevenness in light intensity. The use of such Mercury arc lamp for optically printing the color phosphor screen results in non-uniformity Print result. If the window on the top of the cooling tank is arranged, the heated bubbles rise and remain on the window, so that the disadvantage explained in still more pronounced form occurs.

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In the usual cooling devices, the glass window 9 of a cooling tank 8, in which there is a mercury arc lamp A is located and passes through the cooling water, provided with a glass plate (see. Fig. 2). In such a Trap are therefore light rays 10 from the mercury arc lamp Ί refracted through the glass plate 9 (as with full solid lines illustrated). As a result, seen from the plane 11 illuminated by the light, there is obtained the light source 4 is a virtual light source 12.

In the case of optical printing to produce the color phosphor screen, the light source k is arranged, for example, at the location of the deflection center of an electron beam; the use of a light source which is equipped with a cooling device according to FIG. 2 consequently leads to disadvantages, such as the difficulty in arranging the position of the light source and the lack of uniformity of the light intensity.

On the inner surface of the glass plate 9, a total reflection is also caused in the area in which a large The angle of incidence of the light emitted by the light source 4 is present; through this total reflection it is on the Level 11 decreases falling effective light.

FIGS. 3 to 6 illustrate an embodiment of the invention, which avoids the identified shortcomings of the known designs. A cooling tank 20 has one tubular cavity 20c, the axis X-X of which lies essentially in the horizontal direction and in which a light source, for example a mercury arc lamp 4 is arranged.

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Approximately in the center of the space 20c of the cooling tank 20, a cylindrical cooling water line 21 is arranged along the axis XX, which is made of a transparent material, for example quartz glass with a uniform thickness; The light source Ί is arranged in this line 21. A light window 22 is arranged on the top of the cooling tank 20 at a location opposite the light source 4; a cylindrical transparent window glass 23 made of, for example, quartz glass and having a uniform thickness is connected to the window 22 about the axis XX in a watertight manner using seals 2k. Holders 25 are provided for the window glass 23. The tank 20 contains an inlet channel 26 for introducing the cooling water into the space 20c and an outlet channel 27 for discharging the cooling water from the tank 20. Preferably, the inlet channel 26 and the outlet channel 27 are arranged on one side 20a of the tank 20. The outlet channel 27 is provided on the lower side of the tank 20, in particular below the channel 21.

Near the apex of the cylindrical surface of the transparent window glass 23 is on the side 20a of the Space 20c of the tank 20 a nozzle 28 is provided which opens in the seal of the axis X-X, with the cooling water inlet line 26 communicates, and the cooling water, which is fed through the line 26. Is fed in the form of a jet along the transparent window glass 23 injected.

The outlet line 27 is connected to the line 21 at one End 21a in connection. To connect the inlet line 26 to the nozzle 28 and one end 21a of the line. 21 with the outlet pipe 27 is provided at the end portions 20a of the tank 20 along the axis X-X, a pipe section 29, the Channel 29a watertight with the end 21a of the line 21 in connection 3teht.At points that the inlet line 26 and

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opposite the outlet line 27 on the circumference of the pipe part 29, annular grooves 30, 31 are provided. they are insulated from each other in connection with the inner wall of the cooling tank 20 in a watertight manner and also from the space 20a of the Completed tanks 20. Ring seals 32, 33 isolate the "grooves 30, 31 from one another and the ring groove 31 from the Space 20c of the tank 20. The annular groove 30 is in communication with the cooling water inlet pipe 26 and the nozzle 28. in the In the pipe part 29 there is a radial opening 34 which is connected to the annular groove 31. The other end 21b of the Line 21 opens into space 20c of cooling tank 20. A light source, namely the mercury arc lamp 4, which

Ψ is to be cooled is arranged in line 21 along the XX axis. The electrode terminals ¹ Ia, 4b at both ends of the mercury arc lamp 4 are electrically led out at both ends 20a, 20b of the tank 20th To mechanically hold the mercury arc lamp 4, a conductive rod 35 is inserted into the tubular part 29 and engages the front end with the connection 4a. A conductive adjusting screw 37 is screwed into the head of the rod 35. A conductive spring 36 holds the rod 35 in resilient abutment with the terminal 4a. The adjusting screw 37 is used as an external connection to ground. The other connection ¹ Jb of the mercury arc lamp is led to the outside through an opening 40 in the end part 20b of the tank 20 and is connected to a conductor 38. The connection 4b of the mercury arc lamp 4 is covered by an insulating tube 39, at least in the area which is inserted into the tank 20. This insulating tube 39 has a Plansch 39a, which is connected via an annular seal ² Jl with a level ¹ IOa in the opening 40 in engagement. A cylinder part 42 is screwed into the opening 40 and has screw threads in order to hold the mercury arc lamp 4 in its position.

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The cooling water is supplied through the inlet pipe 26. It flows through the annular groove 30 and emerges from the nozzle 28 (cf. FIG. 5). The sprayed water flows in the inner surface of the window glass 23 from one side 20a of the tank 20 to the other side 20b, so that any bubbles adhering to the window glass 23 are washed away. The cooling water then flows into the line 21 through the open end 21b and reaches the mercury arc lamp 4. It then exits through the pipe part 29, the opening J> k and the channel 27.

The transparent window glass 23 is a cylindrical surface with a thickness j of approximately uniform around the X-X axis The light emitted from the mercury arc lamp 4 is therefore not refracted through the window glass 23 but passes through straight through. This creates a virtual light source and unevenness in light intensity avoided.

Since the nozzle 28 is located opposite the window glass 23 Place, bubbles can be washed away from the window glass. Even when the lighting window is on located on the upper side of the tank, can be accessed on this Catfish prevent bubbles from resting on the window glass. The irregularity in the irradiance mentioned at the beginning can be prevented in this way.

Since the mercury arc lamp k to be cooled is arranged in the line 21, there is a good flow of the cooling water Lamp explosion due to a local rise in temperature and unevenness in the illuminance due to gas bubbles are avoided in this way.

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Since the outlet line 27 is arranged lower than the line 21 is, the replacement of the mercury arc lamp 4 is not difficult. The cooling water is completely withdrawn from line 21 by interrupting the supply of cooling water from line 26 and removing the cooling water is drained from the line 27 in the tank 20. If you now remove the tubular part 42, the mercury arc lamp 4 can be replaced without a leakage flow of cooling water occurring.

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Claims (9)

Claims 11.1 / cooling device, characterized in that that a housing * with an inlet line for the introduction of cooling water, a light source and an outlet line are provided for discharging the cooling water from the housing, that also one with the outlet line in connection standing and the light source containing line is present, furthermore a transparent window through which the light radiation the light source falls to the outside, and that finally there is a nozzle connected to the inlet duct that directs a jet of cooling water near the window. 2.) Cooling device according to claim 1, characterized in that at least part of the line is transparent. 3.) Cooling device according to claim 1, characterized in that the window is arranged on the top of the housing. 4.) Cooling device according to claim 1, characterized in that the nozzle is arranged higher than the discharge line. 5.) "Cooling device according to claim 1, characterized in that that the light source is formed by a mercury arc lamp. · 6.) Cooling device according to claim 5, characterized in that the mercury arc lamp is supported on both sides is. 7.) Cooling device according to claim 6, characterized in that that one of the holders of the mercury arc lamp is connected to the housing by a screw. 009822/132 5 8.) Cooling device according to claim 7, characterized in that for the purpose of replacing the mercury arc lamp a lamp holder is detachable. 9.) Cooling device according to claim 1, characterized in that the window is cylindrically shaped and parallel to the longitudinal direction the light source is arranged. 009822/1325