DE4339950C2 - Device for assembling electron guns - Google Patents

Description

Technical field

The invention relates to a device for Assembly of electron guns according to the Preamble of claim 1, in particular of electrons blasting systems of multi-beam cathode ray tubes. A such a device is e.g. B. known from EP 138 388.

State of the art

Multi-beam cathode ray tubes, for example color picture tubes, are equipped with electron beam generators which, for example, have four grid electrodes which are arranged one behind the other and maintain a mutual spacing, and in which the various grid electrodes which influence the respective electron beam have a grid electrode which is common to all electron beams in the system be formed. Each of these common grid electrodes has a passage opening for each electron beam, it being possible for not only the passage openings in the various common grid electrodes, but also - depending on the design - the passage openings in a common grid to have a different opening size. In general it can be said that the opening size of the through openings in the various grid electrodes increases from the cathode in the direction of the impingement surface of the electron beams. Already at this point it should be pointed out that the through openings do not necessarily have to be holes embedded in flat grid floors, but can also be holes provided with so-called passages, which are formed for electron-optical reasons and which form the respective opening in the grid floor by a tubular extension in extend its depth. Holes of this type provided with passages in grid electrodes can be found, for example, in color picture tubes in the main lens region, ie in the upper part of grid 3 and in grid 4 .

So that these electron gun systems, for example a good one on the screen of a color picture tube Produce imaging performance, among other things required that the common grid electrodes keep a predetermined distance from each other and that the passage openings in a common Grid electrode to the associated passage openings another common grid electrode exactly are aligned. To realize these demands from DE 34 21 384 a device known, each Beam path of the electron gun system over has a mandrel and to adjust the distance between two common grid electrodes has two-part spacer, which is transverse to Beam direction between the two common Grid electrodes can be arranged. For alignment two common grid electrodes by means of the known The arrangement is first a common grid electrode with their through openings pushed onto the mandrels. Then the spacer is inserted into its Position spent and the other common Grid electrode with its through holes on the mandrels postponed so that the two shared Grid electrodes spaced by the spacer  stacked and related to their Passages are aligned with each other.

The alignment of the passage openings in the two Grid electrodes are made so that the mandrels in the areas where they have the passage openings penetrate an elliptical cross-sectional shape or a have a circular cross-sectional shape limited by two tendons. The large ellipse diameter or the diameter of the Circular cross section is equal to the smallest resulting from the Tolerance resulting diameter of the holes or Passages of the respective common grid electrode in order jamming of the grid electrodes when sliding open or Avoid pulling off the grid electrodes. To one Alignment of the openings in the plane transverse to To get the beam direction, the two are radial to Beam direction arranged contact surfaces of a mandrel (preferably the middle mandrel) over the Contact surfaces of the remaining mandrels rotated by 90 ° (EP 0 158 388 and JP 52-15260). Under investment areas are the Areas of the mandrels running radially to the beam direction understood with which the respective mandrels at slid-on grid electrode with the walls of the Passages or the hole edges in contact.

Are the two common grid electrodes by means of aligned arrangement, can by appropriate training of the mandrels further Grid electrodes aligned on the mandrel assembly will. The permanent fixation of the grid electrodes to each other takes place over glass strips that are heated in Condition pressed on the side of the grid electrodes will. After the glass strips have cooled, the Spacers placed in an extended position, see above  that the electron gun system formed by the Thorns can be removed.

For example, if the large diameter of the ellipse which penetrates the holes or passages like that smallest from the tolerance of the hole or draft resulting diameter, the common Align the grid electrodes only relatively imprecisely. This is due to this because in mass production the never use punched openings or passages 100% roundness or the holes subsequent passes never completely parallel to the Beam axes extending walls are formed can. It is therefore necessary that the areas of Thorns that penetrate the holes or passages and the with their contact surfaces with ideal perforation or Swipe training are in contact with them should, all those that occur during punching and still take tolerable deviations from the nominal size into account, by compared to the target diameter of the hole or Passage are formed somewhat smaller.

In this context it is pointed out that especially the passage openings, which are narrow Bridges from the neighboring passage openings spaced tend to be out of roundness. Special problems occur when the walls of the passages are not exact run parallel to the beam axes. In this case if the tolerance taken into account in such cases is too small in the sections to populate the Thorns difficult because such grid electrodes on the Jam thorns. The latter can lead to Force application during the postponement of such Grid electrodes of the opening cross section is changed  or subject the mandrels to excessive wear will.

The invention is therefore based on the object Device for assembling electron beam generating systems according to the preamble of claim 1 specify which eliminates the mounting problems and at the same time it allows grid electrodes with larger Align and connect accuracy to each other.

Presentation of the invention

This object is achieved in that according to claim 1 for aligning passages Grid electrodes the areas of the mandrels, which in Beam direction with the walls of the passages in Are in contact, have a shorter overall length than that Length of the swipes. This ensures that the Thorns, the contact surfaces of which are ideally trained Passages in contact with the walls of the passages come, not over the entire depth of the swaths with the Walls in contact. For not ideal trained passages this means that in Beam direction of reduced length of the system areas such passages tend to tilt less than with conventional, the entire depth of the draft penetrating investment areas is the case. The further one The result is that, for example, in a transverse to Beam direction elliptical cross-section the large Axis of the ellipse more the target diameter of the swipe can be approximated and thus the alignment precision of Grid electrodes on a mandrel arrangement further increased is.  

According to claim 2, the areas of the mandrels, which in Beam direction on the walls of the passages, so trained that they are in point contact Can have beam direction to the walls Grid electrodes to each other with very high accuracy be aligned. Under a point contact All mandrel versions are between the mandrel and the wall understood, their respective investment areas at a Cut a circular or triangular shape in the beam direction To take shape.

An even higher alignment quality of the arrangement is given if the spines according to claim 3 are trained that when pushed on the thorns and there the grid electrode in its final position Contact between mandrel and wall in an area of the Pull-throughs take place directly at the bending radius in the Bottom of the grid electrode connects. This is because for those that are not parallel to the beam direction Walls in the wall areas that are close to the Bending radius are arranged, the offset based on the total depth of such a passage is the smallest.

Do the mandrels have the specified in claim 4 Mandrel cross-section transverse to the beam direction, so a Alignment of the grid electrodes with just two spikes in are caused very accurately when these two mandrels penetrate the outer through holes for alignment. The high alignment accuracy is based on the fact that Do not align with the central openings needs to be resorted to as this, above all if through narrow webs from the outer beam holes are spaced, tend to be out of roundness.

Brief presentation of the figures

Show it:

Fig. 1 a) a section through a device for assembling electron beam and
b) a top view of a device for assembling electron guns;

Fig. 2 a) is another illustration of Fig. 1a
b) a further representation according to FIG. 1b and

Fig. 3 a) is another illustration of Fig. 1a and
b) a further representation according to FIG. 1b.

Ways of Carrying Out the Invention

FIG. 1a) shows a section through a device 10 for assembling electron beam generators along line xx according to FIG. 1b). This device 10 is essentially formed by a base plate 11 , thorns 12 projecting perpendicularly to the plane of the base plate 11 and a two-part spacer 13 . How the spacer 13 , which can be moved radially to the axis of the mandrels 12 , is connected to the base plate 10 is not shown for reasons of clarity. To better understand the invention, two common grid electrodes 14.1 , 14.2 are pushed onto the mandrels 12 according to FIG. 1a). Each of these two hat-shaped grid electrodes 14.1 , 14.2 has three passage openings 16 with a circular cross section in the grid bottom 15 , as better illustrated in FIG. 1b) as a sectional view along the line AA according to FIG. 1a). Each of these passage openings 16 shown in FIG. 1a) is provided with a tubular passage 17 , which connects to the bending radius 18 in the grid floor 15 . Both grid electrodes 14.1 , 14.2 are held at a distance on their mutually facing grid bases 15 by a spacer 13 shown in the inserted state.

In the exemplary embodiment shown with FIGS. 1a) and 1b), the number of mandrels 12 corresponds to the number of through openings 16 in the two grid electrodes 14.1 , 14.2 .

If a grid electrode 14.1 is to be aligned with a further grid electrode 14.2 by means of the device 10 formed from the parts 11 to 13 , the first grid electrode 14.1 with the passage openings 16 is first pushed onto the mandrels and brought into its end position on the mandrels 12 . The latter is realized in the present exemplary embodiment in that the first grid electrode 14.1 rests with its pot edge 19 on the base plate 11 . This grid electrode 14.1 is aligned by means of the spikes 12 , which - as shown in FIG. 1b) - are largely narrower in the beam direction S ( FIG. 1a) than the clear diameter of the passage openings 16 . Only in a region of the passage openings 16 , which merges into the tubular passages 17 following the bending radii 18 , do the mandrels 12 have such a cross section that either in the x-direction or the y-direction has an extension corresponding to the diameter of the passage opening 16 . According to the illustration in Fig. 1b), this is shown by the fact that, in the areas mentioned - transverse to the beam direction - elliptically shaped mandrel cross sections, the large axis diameter of the mandrels 12 for the two outer passage openings 16 extends in the y direction and the large axis diameter of the mandrel 12 , which extends through the central passage opening 16, extends in the x direction. As can be clearly seen from FIG. 1b), the large ellipse diameters, which at the same time form the contact surfaces, lie against the hole edges 20 of the passage openings 16 .

The fact that the elliptical mandrel cross sections, which are shown in FIG. 1 b), do not lie against the walls of the passage 17 over the entire depth, is shown in FIG. 1 a) only for the central mandrel 12 for reasons of drawing. In particular, it can be seen from this illustration that the elliptical cross section of the central mandrel 12 lies only point-wise along the beam direction S on the walls of the passages 17 . This punctiform contact of the elliptical mandrel cross-sections in the beam direction S ensures that the passage openings 16 provided with the passages 17 can be pushed onto the mandrels 12 without problems, regardless of the parallelism of the walls of the passages 17 to the beam direction S, and at the same time with high accuracy the mandrel axes can be aligned. The latter applies all the more, the closer the point contact between the respective mandrel and the wall of the passage 17 is at the bending radius 18 .

If the first grid electrode 14.1 is pushed onto the mandrels 12 and aligned, the two-part spacer 13 is inserted. The further grid electrode 14.2 is then threaded onto the mandrels 12 . When this grid electrode 14.2 reaches its end position on the mandrel arrangement, this electrode 14.2 is aligned with the grid electrode 14.1 by the mandrel design already described in connection with the grid electrode 14.1 .

In a further embodiment (not shown), after the second grid electrode 14.2 is slid on and aligned on the mandrel arrangement, further grid electrodes can be slid on and aligned.

If all the grid electrodes (here only the grid electrodes 14.1 and 14.2 ) are aligned on the mandrel arrangement, these are connected by means of the known glass technique and can then be pulled upwards from the device 10 after the spacers 13 have been removed.

A further embodiment of a device for assembling electron beam generators is shown in FIGS. 2a and 2b). This illustration also shows in FIG. 2a) a section along the line xx according to FIG. 2b). FIG. 2b) shows a top view of the sectional area AA according to FIG. 2a). Also, in Fig. 2a) is provided with through two trains 17 grid electrodes 14.1, 14.2 arranged aligned on a formed of a base plate 11, a mandrel assembly 12 and a spacer 13 device 10.

In contrast to the embodiment according to Fig. 1a) and Fig. 1b) according to the embodiment of FIG. 2, only the two outer through holes 16 are each penetrated by a mandrel 12. As already explained in connection with Fig. 1a) and 1b), the pins 12, which penetrate the outer through-openings 16, against the internal diameter of the passage openings 16 substantially slender formed (Fig. 2a).

So that in this device 10 an alignment of the two grid electrodes 14.1 , 14.2 in a plane transverse to the beam direction S is achieved by the two spikes 12 , the spikes 12 in this exemplary embodiment have an approximately triangular cross-sectional shape transverse to the beam direction S ( FIG. 2b). Two corners of the triangular cross section of each of the two mandrels 12 are in contact with the hole edges 20 , at which the axis Y running through the center of the respective passage opening 16 intersects the hole edges 20 . The 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 mandrel 12 , by this corner having an intersection of an axis running through the center of the respective passage hole 16 and enclosing an angle of 900 to the axis Y. x is in contact. As further shown in FIG. 2b), the third corners of the triangular cross-section in this area face away from the central hole 16 , ie the third corners point in different directions along the axis x.

The regions of the mandrels 12 which, as shown in FIG. 2b) are in contact with the perforated edges 20 , are also not in contact with the wall of the passage 17 over the entire depth of this embodiment. Rather, the respective mandrel cross-section is also shaped here in such a way that in the beam direction S only a point contact occurs between each of the three corners of the triangular mandrel cross-section and the walls of the penetrations 17 ( FIG. 2a). The point contact of the mandrel cross section in the beam direction S has already been discussed above and therefore does not require any further explanation here.

.. If only two mandrels 12 used in the embodiment of Figures 2a) and 2b) for alignment, this has the advantage over the embodiment shown in Figures 1a) and 1b) in addition to the advantage of reducing costs for the mandrel manufacture also has the advantage that. - For example, in the case of a three-beam grid electrode - it is not necessary to use all, but only those passage openings 16 which can be formed with high precision during manufacture. The latter provides the guarantee that the alignment precision of grid electrodes can be further increased by aligning the various grid electrodes 14.1 , 14.2 using only two mandrels 12 .

The representations according to FIGS . 3a) and 3b) differ from the representations of FIGS. 2a) and 2b) only in that the third corner of the triangular mandrel cross section points in the direction of the central passage hole 16 ( FIG. 3b).

Claims (4)

1. Device for assembling electron beam generators multi-beam cathode ray tubes with for receiving grid electrodes ( 14.1 , 14.2 ) which have holes ( 16 ) provided with passages ( 17 ), centering mandrels ( 12 ) which are radial to the beam direction with the edges ( 20 ) of the Passages ( 17 ) are at least partially in contact, characterized in that for the alignment of the grid electrodes ( 14.1 , 14.2 ) the areas of the mandrels ( 12 ) which are in contact with the walls of the passages ( 17 ) in the beam direction (S) have a shorter overall length than the length of the passages ( 17 ). 2. Device according to claim 1, characterized in that the mandrels ( 12 ) in the beam direction (S) have point contact with the walls of the passages ( 17 ). 3. Apparatus according to claim 1 or claim 2, characterized in that the areas of the mandrels ( 12 ) which are in contact with the walls of the passages ( 17 ) in the beam direction (S) in the end position of the respective grid electrode ( 14.1 ; 14.2 ) the thorns ( 12 ) are in contact with the locations of the walls of the passages ( 17 ) which directly connect to the bending radius ( 18 ) of the passages ( 17 ) in the base ( 15 ) of the respective grid electrodes ( 14.1 , 14.2 ). 4. Device according to one of claims 1 to 3, characterized in
that for holding and aligning the grid electrodes, are two pins (12) present, which for deferred grid electrodes (14.1 14.2) and the respective outer openings (16) of the grid electrode (14.1; 14.2) penetrate (14.1 14.2)
that the cross section of the respective mandrel ( 12 ) is essentially triangular in shape perpendicular to the beam direction (S),
that the cross sections of the mandrels ( 12 ) are aligned so that when the grid electrode ( 14.1 ; 14.2 ) is pushed on, two corners of the triangular cross section are in contact with the areas of the walls of the passages ( 17 ), one of which passes through the center of the respective opening ( 16 ) the first axis (Y) whose hole edges ( 20 ) intersect so that the third corner of the triangular cross section is in contact with one of the two regions of the walls of the passages ( 17 ), in which one passes through the center of the respective opening ( 16 ) and to the first axis (Y) at an angle of 90 °, the second axis (x) intersects the edge ( 20 ) of the respective opening ( 16 ), and that the third corners of both mandrels ( 12 ) in opposite directions along the Point axis (x).