PL63747Y1 - Evaporating getter device - Google Patents

Description

2 PL 63 747 Υ1

Pattern description

The object of the utility model is a getter device for cathode ray tube (CTR) vaporization, especially of shallow depth.

As you know, cathode ray tube screens have been used for several decades for the production of television sets and computer monitors. Recently, however, displays of an alternative type have become popular, such as plasma displays (PDPs), and especially liquid crystal displays (LCDs). These displays are especially appreciated for their lower weight and depth with specific screen dimensions (usually given as the length of the screen diagonal in inches). While with cathode ray tubes the depth of the screen increases with the diagonal of the screen in inches (e.g. a 32 '' cathode ray tube screen is 50 cm deep), in a PDP or LCD display, the dependence of depth on the side dimensions of the screen is much less important and the depth of these displays does not exceed 10-15 cm. The reduced depth also means less weight. Thanks to these properties allowing for greater freedom in positioning the display (which can even be hung on the wall), PDP and LCD displays are quickly gaining market sectors previously occupied by cathode ray tubes despite the higher price and some technical drawbacks (for example, the LCD display has a smaller viewing angle and lower brightness). ). To overcome this problem, some manufacturers are developing a cathode ray tube with a reduced depth not exceeding 35 cm even with a screen diagonal of 40 ''. 4 shows this new type of cathode ray tube schematically in section. Like all cathode ray tubes, it is composed of a vacuum glass envelope having a back F and a front S, which is the actual screen. The G-electron launcher is located in part F. The electrons emitted by this launcher are deflected by the magnetic field generated by the Y-yoke and directed to the screen, where the phosphor elements forming the image are excited. The difference between such a new cathode-ray tube and traditional lamps lies in the profile of the part F, which is much more flattened in the area adjacent to the yoke Y. The deflection Y assembly, which has to direct the electrons along much more arcuate paths, has larger dimensions compared to traditional cathode ray tubes.

It is known that in order to maintain a vacuum in a cathode ray tube during its lifetime, vaporizable getter devices are used which contain open metal (usually steel) mounts containing at least a barium compound (or less commonly calcium) which are located inside the lamp, usually in approximately at the center of portion F, with their opening facing inside the lamp. After the lamp has been pumped out and sealed by induction heating (with a winding placed appropriately outside the lamp), the barium is evaporated. It solidifies on the inner walls of the lamp to form a metallic film capable of chemically trapping trace amounts of gases permeating into the lamp's interior during its service life to maintain the required level of vacuum.

The getter device is positioned where it is needed by means of a bent metal bracket, known in the art as a spring, attached to the launcher and is spaced from the glass wall of the lamp by a spacer made of metal wire with a non-circular cross-section because when positioning the getter, some this slides along the inside wall of the normally graphite coated portion F to ensure its constant potential, and the sharp edged spacer would damage the graphite layer when inserting the getter device into the lamp, thereby altering the correct operation of the cathode ray tube. Vaporizable getter devices are known, for example, from U.S. Patent Nos. 4,323,818, 4,642,516 and 4,961,040.

A problem with the use of the known getter devices in cathode ray tubes of the new type is that their overall depth is excessive, thereby disturbing the path (shown schematically by the broken line in Fig. 4) of the electrons that are supposed to excite the outermost part of the screen. This causes a dark spot to appear on the side of the display. Merely reducing the thickness of the assembly including the holder, spring and spacer is complicated by certain functional limitations. It is impossible to reduce the height of the side walls of the holder, since these walls have an influence on the direction of the bar vapor, which prevents them from settling in undesirable places. The height of the spacer must not be reduced below certain limits, so that during the induction heating of the holder it is not possible to reach temperatures above 1000 ° C at this stage, which may damage the glass of part F, spoiling the integrity of the lamp. Finally, the free ends of the spacer, which is usually C-shaped with a different outline, as disclosed in U.S. Patent No. 4,323,818, must not be too close to the bottom of the holder so that electrical discharges cannot arise between the two parts during induction heating, causing local cast melts, aggravating bar evaporation. It has been experimentally verified that the minimum distance between said free ends and the base of the stock may not be less than 0.5 mm.

The purpose of the utility model is therefore to provide a vaporizable gether device which does not have the above-mentioned drawbacks.

Vaporizable getter device for cathode ray tubes having an upwardly open holder containing at least one barium or calcium compound attached to a spring for connection to an electron gun, which spring is attached to a spacer consisting of a central part and two arms according to The utility model is characterized in that the free ends of the legs of the spacer are located outside the holder area, and each leg of the spacer has an elbow, the total thickness of the holder, spacer and spring assembly being not more than 6 mm. In particular, the holder has the shape of an annular channel with a substantially rectangular cross-section. In particular, the holder has an annular recess at its bottom.

The object of the utility model is shown in the drawing, in which Fig. 1 shows the getter device in a view from the bottom of the holder, Fig. 2 - a getter device in cross section, Fig. 3 - spacer used in the getter device according to the utility model in a detailed perspective view, and Fig. 4 is a schematic cross-sectional view of the cathode ray tube for which the device is intended according to the utility model.

The getter device 10 shown in Figures 1 and 2 has an upwardly open holder H, inside which are disposed compressed powders 12 of a barium compound, usually BaAI4 (normally mixed with nickel powder), calcium, e.g. calcium-rich Ca-Ba alloy, as disclosed in US Patent No. 6,793,461 B2 (normally in admixture with powdered titanium). The container is shown as a simple low cylinder with a closed bottom, but other shapes are also possible, such as an annular channel with a substantially rectangular cross section, the central part of which is closed or open. Moreover, although such elements are not shown in the drawing, it is possible for the bottom of the holder to be formed as an annular recess of the type disclosed in US Patent No. 4,642,516 or in international patent application PCT / IT2005 / 000326.

A metal spring 14 (only one end attached to the device is shown) is attached to the bottom of the holder H, for example by means of two spot welds 13, 13 ', which connects this device to the electron gun to ensure that the device is precisely positioned during the manufacture of the cathode ray tube. as well as maintaining this position throughout the life of the lamp. This metal spring is essentially a steel strip a few millimeters wide and typically less than one millimeter thick. In order to further reduce the overall thickness of the getter device, the thickness of this spring is preferably about 0.5 mm.

A spacer 15, typically made of steel wire, e.g. approx. 1 mm in diameter, is in turn attached to the spring 14 on the side of the strap opposite the mounting side of the holder li. the spring and the spacer are secured to each other by welding. The spacer 15, shown in plan view in Fig. 1, has a central portion 16 and two arms 17, 17 | each having an elbow 18, 18 | (only one elbow 18 is shown in Fig. 2) and the free end 19, 19. These two elbows assist in sliding over the inner surface of part F as the device is inserted into the cathode ray tube. The free ends 19, 19 'of the legs 17, tT of the spacer 15 are situated outside the holder area 11.

Figure 3 shows the geometrical shape of spacer 15 in its preferred embodiment where its center portion is crushed and has a locally flat section conducive to welding to a spring 14 as known to those skilled in the art.

Of course, the above-described and illustrated embodiment of the getter device according to the formula is only an example in which many changes can be made. In particular, the exact shapes and dimensions of its components can be slightly varied with respect to the typical values given above, if the required mechanical strength of the device is maintained and its overall thickness is less than 6 mm (with a tolerance of at most 0.2 mm).

Claims (3)

4 EN 63 747 Υ1 Protective Claims 1. A vaporizable getter device for cathode-ray tubes having an upwardly open holder containing at least one barium or calcium compound attached to a spring for connection to an electron gun, which spring is attached to a spacer composed of a central part and two arms, characterized in that the free ends (19, 19 ') of the legs (17, X7) of the spacer (15) are located outside the mounting area (11), and that each arm (17, ΥΓ) of the spacer ( the spacer (15) has an elbow (18,18 '), the total thickness of the assembly consisting of the holder (± 1), spacer (15) and spring (14) is not more than 6 mm. 2. The device according to claim The device of claim 1, characterized in that the holder (H) has the shape of an annular channel with a substantially rectangular cross-section. 3. The device according to claim The holder of claim 1, wherein the QD holder has an annular recess at its bottom.