DE1901369B2 - TENSION FRAME FOR THE GRID STRUCTURE OF A COLOR PICTURE REPRODUCTION TUBE AND METHOD FOR MANUFACTURING THE GRID STRUCTURE - Google Patents

Description

The invention relates to a tensioning frame for one of a plurality of flexible wires Grid structure of a color picture display tube with two parallel support arms between which grid wires are located extend, and with two struts connecting the support arms at their ends. Such a lattice structure is in color display tube !! used as a shadow mask. The color phosphors on the When using such a grid structure, screens have the form of parallel strips, The Lattice structure acts on the three electron beams generated in the color display tube as

ίο aperture, such that one of the electron beams only the red color phosphors, the second electron beam only the green color phosphors and the third electron beam can only hit the blue color phosphors.

There is a lattice structure known (German Auslegeschrift 1018 454), in which the giner wires are attached to a frame with putty. The one-piece frame is rigid and roughly rectangular in shape. It is also known a lattice structure (U.S. Patent No. 2,739,263), in which the lattice wires to their ends are guided over support arms, which are opposite parts of an approximately rectangular rigid frame.

The well-known 'lattice structures have the disadvantage that the grid wires expand when heated due to the impact of electrons, which causes their tension easing The release of the tension can lead to sagging of the grid wires, as a result of which the image quality is deteriorated. In addition, the known lattice structures still have the Disadvantage that the tension of the grid wires in the central area of the frame is necessarily greater is than the tension of the grid wires at the two ends of the frame. The reason for this is that the corresponding support arms of the frame are supported at their ends by the cross struts. at a heating of the grid wires as a result of electron impact, therefore, the outer grid wires are more likely sag than the middle gilter wires.

The invention is therefore based on the object of providing the grating structure for a color display tube and in particular to design the frame of the lattice structure in such a way that the lattice wires are also called heating are still under sufficient tension. The influence of thermal expansion should be at all lattice wires of the lattice structure must be the same, starting with a tenter frame of the opening

The type described is intended to provide a solution to the problem order in that the struts support the support arms resiliently in their Bcssclpunktcn and that the resilient struts are pretensioned such that "-ic the support arms in the direction of the lattice wires, juxtaposed / u pull nikI.

Used to maintain tension Struts can be designed, for example, C-shaped The inventive training of the instep

frame also helps ensure that vibrations de Grid wires as a result of slight knocks to which the color display tube is exposed be prevented. In order to completely suppress the vibrations, a further training measure can be used consist in the fact that a damping slab is placed over the grid wires. In this context, sol it should be noted that it is known (according to the German Auslege writings 1 018 454 and 1 149 383), Vi counteract the brations of the grid wires in this way.

The damping siab can be stretched between the two tension-maintaining struts. The damping rod is preferably designed to be flexible and fastened in the middle of the struts. Of the The damping rod should spring against the grid wires. So that the damping rod does its job can optimally meet, it should have a diameter of less than 100 microns. In practice it works proven to be most beneficial when the damping rod has a diameter between 30 and 50 microns. For image reproduction, it has also proven to be advantageous to place the damping rod at an angle to the Arrange grid wires.

The invention also relates to a method for producing a lattice structure of the type described above Art. In a known method, a variety stretched by parallel grid wires with a given tension in a main frame. At- »Finally, a lattice frame is placed on the lattice wire from the inside of the main frame and the Lattice wires on a pair of opposing support screens of the lattice frame. This manufacturing process is relatively complicated.

A simpler production method for the lattice structure according to the invention is now specified, that should consist in the fact that a large number of grid wires are first made from a sheet of flexible material forming strips are formed, which have a distance to the edge of the sheet that oas sheet is then tensioned between tendons, the dam. support arms connected by struts next the ends of the strips are connected to the sheet and that finally those protruding beyond the support arms Edge areas of the sheet are removed. Embodiments of the invention are given below described on the basis of the drawings. It / own

Fig. 1 and 2 schematic representations for Lr-

Ringing of the invention.

F i tr. 3 cine plan view of an example of a grid construction for a color cathode ray

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The support rods 4 and 4 'can be formed from a Me tall such as iron or stainless steel or the like. In the example shown, the support rods 4 and 4 'have a square cross-section and are bent to adapt to the subject in which the grid structure is to be installed. The resilient supports 5 and 5 'can also be made of a metal such as iron, stainless steel or the like and are essentially C-shaped so that they do not interfere with the radiation of the phosphor screen excited by the electron gun of a cathode ray tube. The resilient struts 5 and 5 'can be designed in various ways, as long as they do not interfere with the electron beam directed towards the fluorescent screen of the cathode ray tube. The grid elements 6 can also be formed from a metal such as iron, stainless steel or the like. With this arrangement, the support rods 4 and 4 'can undoubtedly be regarded as a solid body with respect to the load caused by the tension of the grid elements, since the support rods 4 and 4', which form part of the frame, with the resilient struts 5 and 5 ' is connected as a unitary body in or in the area of the Bessel points B _A , Bn and B / and Bn ' . It follows that the grating elements between the support rods 4 and 4 'ind ^c biased with uniform predetermined train, although expand under the effect of heat by the incident electron beam, but the support rods 4 and 4' in turn by the resilient struts 5 and 5 'are pulled apart in parallel assignment by a distance corresponding to the length expansion of the gilter elements elongated by the thermal expansion. As a result, the initial distribution of the tensile stress over the entire grid elements remains unchanged, although the absolute value of the tensile stress deviates from the original.

The above description has been made on the basis of a lattice structure in which the lattice elements at the two end regions and the central region of the support rods have substantially the same length, so that they elongate substantially the same as a result of thermal expansion. Tests carried out accordingly on a lattice structure in which the support rods of square cross-section consisted of stainless steel and which had dimensions of approximately 10 × 240 mm and in which the 400 lattice elements had a width of 0.5 mm. a thickness of 0.1 mm and a length of about 180 mm (length of the grid elements between the end areas of the support rods = 175 mm; length of the elements in the middle area = 185 mm) between the support rods with a tension of approximately 350 g for each grid element have shown that even when the grid elements were heated by electron beams and expanded by thermal expansion during use, deficiencies such as vibration of the grid elements due to non-uniform tension or color shifts due to irregularities in the distance between adjacent grid elements did not occur. Furthermore, it has been found that the deviation from the original stress distribution of the grid elements as a result of the thermal expansion of the same, caused by the impact of the electron beam, by expansion or shrinkage of the grid elements or slight restoring forces of the support rods is compensated.

In addition, it has been found that when the deviation in the length of the grid elements is in a range of ± 20 ⁿ / ₀ relative to their mean dimension, the linear expansion of the grid elements due to thermal expansion is very small and that the initial distribution of the tensile stress of the Grid elements is maintained during the use of the grid structure by expansion or shrinkage of the grid elements or compensation by the restoring force of the support rods.

The grid structure is built into the cathode ray tube as follows: On the resilient struts ^ and 5 'with the support rods, for example 4. each resilient parts of a predetermined shape are attached, each of which has a bored opening at its free end. An elongated hole is preferably provided in the direction of the grid elements in at least one of the resilient parts which are attached to the resilient supports. On the inside of the installation compartment for the grid, projections are provided which are pushed into the openings in the resilient parts in order to : Install the grid structure in the compartment in the cathode ray tube. In this case, the resilient parts and the corresponding projections in the installation compartment can be four in number.

In the known lattice consummations, a very complicated device is necessary in order to tension the lattice elements in the lattice frame, but this can easily be achieved by the following method. For example, as shown in Fig. 5, a stainless steel thin plate of a predetermined size is first prepared and etched to remove certain areas so that metal strips Sa are formed at a predetermined interval. At the same time, 8 "slots 8" are formed at the two border areas of the plate 8 in a predetermined number per strip (one slot for every third strip as shown). In the same way, slots 8r are formed in the plate 8 on both sides of the metal strips Sa. Then, as shown in FIG. 6, the divided regions by the slits Sb 8r / each clamped in chuck 9 A and 95th In this case, the number of chucks 9, -1 and 9 5 corresponds to the number of areas Sd. The chucks 9 B are under variable tension according to the thickness and quality of the material of the areas Sd. The tensile stress can also be given to both chucks 9.4 and 9 5. Substantially the same tension is applied to the metal strips by means, for example, as shown in FIG. 6 shown, by a spiral spring 10. In this tensioned state, a pair of support rods 11 and 11 'are brought at predetermined positions under the plate 8 and "the plate 8 is welded to the support rods. In this case, the support rods 11 and 11' are through a A pair of resilient brackets are held at or near the fastening points, although not shown, and the resilient brackets are bent slightly inward to give the metal strips a predetermined tension when the areas Sd are removed from the chucks 9.4 and 95. Preferably is the force for bending the two resilient struts is equal to the tensile stress (the total stress applied to all of the metal strips) applied to the metal strips Sa by the spring 10.

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In this way, after removal of the chuck 9 A is formed in pieces in the area of the projections 13 ″

£ "custom 8 to erlrichtern thus they are not always Ϊη J, i, Lt nowe dip;. Au, the above-described Ar can SätL 'the metal strip 8" easily be-.

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further IM e _S difficult the stress equilibrium, ^^ thermal expansion of the frame or the grid elements 14 as a result of temperature increases? disturbing during use, and even if the balance of tension is lost, _the tensions immediately equalize. so that the deformation of the frame is extremely weak. It follows that the position of the grid elements 14

Ä brought tensile stress

""nfe'ESoiensUahl permeability depends on the RrSr of the Meui strips or the diameter and the shedding of the metal wires. which _we normal, se USER, are un, the Etek ^ stjajldurd -

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. ^In T F InL ^ darKStem where the entire form of the invention is shown, where g

SS eÄ TTr ^ XuTnIa 12 'are of

^ Vr frame-like resilient strut 13 in den or emer rahmenahni.cnen eae ^ _ejn

meTvor'egeberer S ^ arises. Lattice elements H Fo "Γνοη, for example, metal strips are between

_{$ ch} en demPaar ^^^^ ί ^ δί ^ ί Ä tensioned. The Tragerp hitten IZ una iz

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Side edge of each support plate ^ arch, st, ^

t'ihlrSLe in de the finished lattice construction to-beam pipes, in J «J« ^e ™ 8 _{dj resilient strut} 13

SnTaS "e nem Me a ,, like iron, stainless steel. Od dd« biwS, whereby it. As shown in Fig. 10 at points which essentially correspond to the Bessel points η -rfllr, atten 12 and 12 ', Projections £, IS s des wise, the strut 13 has L-shaped members 13b receiving support plates, which can act on the screen, so that the color shift does not occur and clearer images are ensured. In addition, the lattice construction described above is extremely simple in structure, the manufacture is very simple.

Even if the grid elements 14 are tensioned between the carrier plates 12 and 12 'with essentially the same tensile stress, the deformation of the frame, as shown in dashed lines with the line B in FIG. 2, is only very weak. Thus, there is also no possibility that the position of the grid elements 14 shifts due to such a slight deformation of the frame, due to thermal expansion of the grid elements or due to temperature expansion of the frame. This means that the aforementioned numerous advantages can also be achieved with the grid elements 14 tensioned with uniform tensile stress.

The installation of the grid structure in the cathode ray tube can easily be done by the same already it Means mentioned are made or by other known means, so that a more detailed description is not necessary is agile. Needless to say, dai the aforementioned means for stretching de lattice elements can also be used and aucl Metal wires in place of the metal strips as grid elements 14 who are used at a predetermined distance the can.

The support rods and the support plate :! are to be made of conductive material so that no electrical see fields between the girders and the grids

109 584/10

elements arise. The training of this carrier is not limited to the support bars and support plates.

When using the grid construction in color television tubes ./earth the pointer elements by mechanical means Vibrations caused by external shocks or by electron beam bombardment to vibrate. 11 to 13 is yet another embodiment of the invention shown in which the grid structure is designed so that these undesirable Vibrations of the grid elements: i; are avoided.

In the drawings, the numbers 21 A and 21 B designate a pair of support rods 22 A and 22 B , essentially C-shaped resilient supports, which carry the support rods 21 A and 215 in or in the area of the Bessel points, around a lattice frame, which as a whole is denoted by 23. to build. With 24 lattice elements are designated, for example those made of band-shaped metal strips, which are spanned with a predetermined stress distribution and spacing between the pair of support rods 21 A and 21 B. These parts are identical to the parts described in the previous examples.

In the present embodiment, a Damping rod, for example formed by a metal wire, is provided, which rests against the Git: i: reIementen24.

Sd are, for example, attached to the outer sides of the resilient struts 22/1 and 225, essentially in the middle of the same, 'resilient pieces': 2b A and 26 5 and the damping rod 2: 5 is stretched between these resilient pieces 26A and 26 5. In this case, the damping rod 25 is stretched in one direction of the raster (in the electron beam scanning direction), but it is preferred that the damping rod 25 is stretched obliquely at an angle of about 30 to 45 to the electron beam scanning direction.

By this arrangement, the grid elements 24 are resiliently pressed by the damping rod 25 and as a result, they cannot do so due to external mechanical impacts or electron beam bombardment vibrated. Even if there is a vibration, the Damping rod 25 suppressed, whereby the adverse influence of vibration on the CJ otter elements avoided is. The arrangement of the damping rod 25 not only avoids the vibrations of the grid elements, but also prevents irregularities in the distances between the elements which can be caused by twisting. In particular if the grid elements 24 by the impact of the The electron beam is heated and twisted as a result of thermal expansion, pressing the damping rod 25 the grid elements 24, so that a rotation of the grid elements in compliance with the predetermined Distance between adjacent grid elements is avoided and it is ensured that the Electron beam acts only on the specified phosphor strip. The damping rod 25 is very light to be attached as it is only in contact with the surfaces the grid elements is to be tensioned. The damping rod 25 can be a mechanically strong metal wire, For example made of tungsten, stainless steel or the like. Be. The use of such a mechanically solid Wire avoids breaking the damping rod or insufficient pressure on the grid elements. What happen with the usual damping rods made of fiberglass in grid structures for Chromatron color tubes can be avoided.

Damping rods 25 made of the aforementioned metals or other metals are preferred because of them mechanical strength and the lack of secondary electron emission. Preferably the diameter is of the damping rod 25 is 30 to 50 microns. With a diameter of, for example, 100 microns, it is true the mechanical strength of the damping rod is increased, but then by the damping rod adversely affects the reproduced images. With a diameter of less than 30 microns it takes up the mechanical strength of the rod 25 decreases, and its pressing action on the grid elements becomes insufficient. Correspondingly, the smaller diameter of the damping rod is the unfavorable one Influence on the reproduced image diminished, but the influence of a damping rod up to 50 microns on the reproduced image is hardly noticeable. On the basis of tests carried out, a tungsten wire is included 30 to 50 microns in diameter give good results. In the aforementioned embodiment, the Damping rod 25 stretched between the two resilient parts 26.4 and 265, but one can or both of these parts can be omitted. The shape and position of the resilient parts is not dependent on that example shown is limited. For example, it is possible that resilient wires in the frame too both sides of the grid elements are tensioned in place of the resilient parts and the damping rod between these two resilient wires is tensioned. Furthermore, the damping rod 25 to the Grid elements 24 be attached.

For this purpose 3 sheets of drawings

Claims (10)

Patent claims: 1. Tenter frame for a lattice structure formed by a plurality of flexible wires of a color picture display tube with two parallel support arms, between which the lattice wires extend, and with two struts connecting the support arms at their ends, characterized in that the struts (5,5 ';13; 22/1, 225) support the carrier arms (4,4 ';12,12'; 21 A, 21 B) resiliently in their Besselpunkien (ß.i, Bn, B .. \ ', Bn') and that the resilient struts are pretensioned in such a way that they seek to pull the support arms apart in the direction of the grid wires (6,14, 24). 2. Clamping frame according to claim], characterized in that the struts (5,5 '; 22 A, 22B) are essentially C-shaped. 3. Clamping frame according to claim 1 or 2, characterized in that the flexible grid wires a damping rod (25) is placed in order to prevent mechanical vibrations of the grid wires (24) suppress. 4. Clamping frame according to claim 3, characterized in that the damping rod (25) is tensioned between the two struts (22/1, 22 B). 5. Clamping frame according to claim 3 or 4, characterized gekc !!! characterized in that de ^r dampening bar is flexibly mounted and in the Mitlo of the two struts (22/1, 12 B) (25). 6. Clamping frame according to one of claims 3 to 5, characterized in that the The damping rod (25) is resiliently pressed against the flexible grid wires (24). 7. clamping frame iiach one of claims 3 to 6. characterized in that the damping rod has a diameter of less than 100 microns Has. S. clamping frame according to claim 7, characterized in that the damping rod (25) has a 30 to 50 microns in diameter. 9. Clamping frame according to one of claims 3. 4 or 6 to 8, characterized in that cli'i Damping rod (25) is arranged obliquely to the grid wires (24). 10. A method for producing a lattice structure clamped in a tenter frame according to one of the preceding claims for a I arhbildw icderg;> touch, characterized in that a plurality of strips (Ha) forming lattice wires are initially formed from a sheet (.S) of flexible material which are at a distance from the edge of the sheet (8) so that the sheet (8) is then tensioned between tension members (9, -1, 9B) , the support arms (11, W) then connected by struts next to the ends the strip (8 ″) are connected to the sheet (8) and that finally the edge regions of the sheet (8) protruding beyond the support arms (11, 1Γ) are removed.