NL194452C - Device for the structural joining of electron beam generators of cathode ray tubes. - Google Patents

Description

1 194452

Device for the structural joining of electron beam generators of cathode ray tubes

The invention relates to a device for constructively joining electron-beam generators of cathode-ray tubes with various electron beams and comprising centering pins for receiving grid electrodes having holes provided with passages, which pins radially with respect to the edges of the electron-beam device. passages are at least partially in contact.

Such a device is known from the European patent application EP-A-0.158.388. This document 10 describes a device for assembling an integrated electron gun system of an 'in-line' color display tube. This electron gun system comprises a number of electrodes centered around an axis. The device comprises three centering pins whose longitudinal axes are substantially in The electrodes are placed on the pins and then mechanically fixed with respect to each other Only certain parts of the centering pins are in contact with openings 15 in the electrodes, the diameter of the outer electrodes being perpendicular to said plane and the diameter of the middle electrode is in the said plane.

The object of the invention is to provide a device of the type described in the preamble which solves equipment problems and at the same time makes it possible to align and connect grid electrodes with greater accuracy relative to each other.

This object is achieved by the fact that, for aligning the grid electrodes, the regions of the pins which are in contact with the walls of the passages in the electron beam direction have a shorter length than the length of the passages. This ensures that the pins, the device surfaces of which come into contact with the walls of the passages with ideally shaped passages, are not in contact with the walls above the total depth of the passages. For passages that are not ideally formed, this means that with the length of the tangent regions reduced in the radius direction, such passages tend to tilt much less than is the case with conventional tangent regions penetrating the total depth of the passageway. The further consequence is that, for example, with an elliptical cross-sectional cross-sectional area the larger axis of the ellipse can more closely approximate the desired diameter of the passage and thus the alignment accuracy of grid electrodes on a pin device 30 is further increased.

The invention will be further elucidated with reference to the drawing. Therein: figure 1a shows a horizontal section through a device for the construction of electron beam generators and b a front view of a device for the construction of electron beam generators; figure 2a a further representation according to figure 1a b a further representation according to figure 1b and figure 3a a further representation according to figure 1a and b a further representation according to figure 1b.

40

Figure 1a shows a cross-section through a device 10 for the construction of electron beam generators along the line x-x according to Figure 1b. This device 10 is essentially formed by a base plate 11, pins 12 protruding perpendicular to the plane of the base plate 11 and a two-part spacer piece 13. How the spacer piece 13, which can radially rotate with respect to the axis of the pins 12, 45 being connected to the base plate 11 is not shown for the sake of clarity. For a better understanding of the invention, two common grid electrodes 14.1, 14.2 are slid onto the pins 12 according to Figure 1a. Each of these two hat-shaped grid electrodes 14.1, 14.2 has three passage openings 16 with circular cross-section in the grid bottom 15, such as Figure 1b. as a cross-sectional view along line AA according to figure 1a, each of these passage openings 16 visible in figure 1a 50 is provided with a tubular shaped passage 17 which connects to the radius of curvature 18 in the grid bottom 15. Both grid electrodes 14.1, 14.2 are held at a distance on their facing grid bases 15 by a spacer 13 shown in the retracted state.

In the exemplary embodiment shown in Figs. 1a and 1b, the number of pins 12 corresponds to the 55 number of passage openings 16 in the two grid electrodes 14.1, 14.2.

If, by means of the device 10 formed from parts 11 to 13, a grid electrode 14.1 is to be aligned with respect to a further grid electrode 14.2, first of all the first 194452 grid grid 14.1 with the passage openings 16 is slid onto the pins and inserted into the pins end position thereof on the pins 12. The latter is realized in the present exemplary embodiment by the fact that the first grid electrode 14.1 with its pot edge 19 lies on the base plate 11. Alignment of this grid electrode 14.1 takes place by means of the pins 12, which - as Figure 1b shows - are formed in the radius direction S (Figure 1a for the most part narrower with respect to the inner diameter of the passage openings 16. Only in one In the region of the passage openings 16, which, following the radius of curvature 18, merges into the tubular passages 17, the pins 12 have such a cross-section which, either in the x-direction or in the y-direction, has a diameter of has a corresponding extension through aperture 16. According to the representation in Figure 1b, it can be seen that, in the aforementioned areas - crosswise to the direction of the beam - elliptically shaped pin cross-sections have the large shaft diameter of the pins 12 for the two outermost apertures 16 extends in the y direction and the large axis diameter of the pin 12, which extends through the middle passage opening 16, extends in the x direction. As can clearly be seen in Figure 1, and the large ellipse diameters, which at the same time form the interfaces, abut the hole edges 20 of the passage openings 16.

The fact that the elliptical pin cross-sections, shown in Figure 1b, do not rest against the walls thereof above the total depth of the passages 17, is shown in Figure 1a only for the middle pin 12 for technical reasons of drawing. In particular, in this representation it can be seen that the elliptical cross-section of the middle pin 12 along the radius direction S is only point-shaped against the walls of the passages 17. This point-shaped contact of the elliptical pin cross-section in the radius direction S provides the guarantee that the passage openings 16 provided with the passages 17 independently of the parallelism of the walls of the passages 17 with respect to the radius direction S on the pins 12 are problem-free. can be moved up and at the same time aligned with high precision with respect to the pin shafts. The latter applies all the more as the point-shaped contact between the respective pin and the wall of the passage 17 is closer to the radius of curvature 18.

When the first grid electrode 14.1 is slid onto the pins 12 and aligned, the two-part spacer 13 is slid inward. Then the further grid electrode 14.2 is plugged onto the pins 12. When this grid electrode 14.2 reaches its end position on the pin device, this electrode 14.2 is aligned with respect to the grid electrode 14.1 by the pin shape already described in connection with the grid electrode 14.1.

In a further - not shown - exemplary embodiment, after the second grid electrode 14.2 has been moved up and aligned on the pin device, further grid electrodes can be moved up and aligned.

If all the grid electrodes (here only the grid electrodes 14.1 and 14.2 are aligned with the pin device, they are connected by known gias connection technology and can then be pulled upwards from the device 10 after the spacers 13 have been removed.

Figures 2a and 2b show a further exemplary embodiment of a device for the construction of electron beam generators. This representation also shows a cross-section along the line x-x according to figure 2b in figure 2a. Figure 2b shows a top view of the cutting surface A-A according to Figure 2a. In Fig. 2a also two grid electrodes 14.1, 14.2 provided with passages 17 are arranged on a device 10 formed from a base plate 11, a pin device 12 and a spacer piece 13.

In contrast to the shape according to figure 1a and figure 1b, according to the embodiment according to figure 2, only the two outer passage openings 16 are penetrated by a pin 12. As has already been explained in connection with Figures 1a and 1b, the pins 12 which penetrate the external passage openings 16 are also substantially slimmer in relation to the inner diameter of the passage openings 16 (Figure 2a).

In this device 10, so that the two pins 12 achieve alignment of the two grid electrodes 14.1, 14.2 in a plane transverse to the beam direction S, the pins 12 in this exemplary embodiment have an approximately triangular cross-sectional shape transverse to the beam direction S (Figure 2b). two corners of the triangular cross-section of each of the two pins 12 are in contact with the hole edges 20 at the point where the axis Y running through the center of the respective passage opening 16 intersects the hole edges 20. Alignment of the grid electrodes 14.1, 14.2 in the x direction takes place via the third corner of the triangular cross-section of each pin 12, in that this angle with an intersection of an angle passing through the center of the respective passage hole 16 and an angle with respect to the axis Y 55 is in contact with the axis x of 90 [deg.], As shown in Figure 2b, the third angles of the pin-shaped cross section of the m middle hole 16, i.e. the third angles point in different directions along the axis x.

Claims (4)

1. Device for constructively joining electron-beam generators of cathode-ray tubes with various electron beams and comprising centering pins for receiving grid electrodes having holes provided with passages, which points are radially relative to the electron-beam device with the edges of the passages at least partially are in contact, characterized in that for aligning the grid electrodes (14.1; 14.2) the regions of the pins (12) which are in contact with the walls of the passages (17) in the electron beam direction (S) have a shorter length than the length of the passages (17). Device according to claim 1, characterized in that the pins (12) make point-shaped contact with the walls of the passages (17) in the jet direction (S). Device according to claim 1 or 2, characterized in that the regions of the pins (12) which are in contact with the walls of the passages (17) in the radial direction (S), at the end position of the respective grid electrode ( 14.1; 14.2) on the pins (12) in contact with those positions of the walls of the passages (17) which are directly on the bending radius (18) of the passages (17) in the bottom (15) of the respective Connect the grid electrode (14.1; 14.2). However, in this exemplary embodiment, the regions of the pins 12 which, according to the representation in Figure 2b, are in contact with the hole edges 20 are not in contact with the wall thereof above the total depth of the passage 17. Rather, here too, the respective pin cross-section is formed in such a way that in the beam direction S only a point-like contact is made between each of the triangles of the triangular pin-cross section and the walls of the passages 17 (Figure 2a. contact of the pin cross-section in the jet direction S has already been discussed further above, and this therefore requires no further explanation If, according to the embodiment according to Fig. 2a and Fig. 2b, only two pins 12 are used for alignment, then this has compared to the embodiment according to figures 1a and 1b, in addition to the advantage of cost reduction for the manufacture of the pin, also the advantage that - for example in the case of a three-ray grid electrode - it is not necessary to use all of the passage openings 16 for alignment, which only can already be manufactured with high accuracy during manufacture, the latter guaranteeing that bi j aligning the different grid electrodes 14.1, 14.2 using only two pins 12 the alignment accuracy of grid ore electrodes can be further increased. The representations according to Figs. 3a and 3b are distinguished from the representations of Figs. 2a and 2b only in that the third angle of the triangular pin cross-section points in the direction of the central through-hole 16 (Fig. 3b). 20 Device as claimed in any of the claims 1 to 3, wherein two pins are provided for receiving and aligning the grid electrodes which, with the grid electrodes slid through, penetrate the respective outer passage openings of the grid electrodes, characterized in that the cross-section of the 40 respective pin (12) is substantially triangular shaped transversely to the radius direction (S), so that the cross-sections of the pins (12) are aligned such that with the grid electrodes (14.1; 14.2) pushed up, two angles of the triangular cross-section are in contact with those areas of the walls of the passageways (17), where a first axis (Y) provided through the center of the respective aperture (16) intersects its hole edges (20) and the third corner of the triangular section is in contact with one of the two regions of the walls of the passageways (17), in which one present through the center of the respective opening (16) and The first axis (Y) enclosing a 90 ° angle second axis (x) intersects the edge (20) of the respective opening (16) and that the third angles of the two pins (12) in opposite directions along the second axis ( x) point. Hereby 3 sheets of drawing