WO2004086450A1 - Masking device for a cathode ray tube - Google Patents

Abstract

The inventive cathode ray tube comprises a colour selection mask (8) tensioned by a metal frame (19). Antivibration means (155) for said mask are disposed on at least one side and periphery thereof and are embodied in the form of a flexible metallic strip (155) whose one part is welded to the peripheral area of said mask, the other part thereof being movable by mask vibration. Said metallic strip is embodied in such a way that the width thereof gradually increases away from the ends (152) towards the central part (151) thereof, thereby increasing the lateral rigidity of said strip.

Description

 MASKING DEVICE FOR TUBE WITH CATHODE RAYS

The present invention relates to a color selection mask structure for a color cathode ray tube. The invention finds its application in any type of tube comprising a mask for selecting colors and is equally well suited to tubes whose mask is held in tension by the frame on which it is secured as to tubes whose mask is formed by stamping and welded to the support frame. Conventional cathode ray tubes have a color selection mask located at a precise distance from the inside of the glass front face of the tube, the front face on which are deposited arrays of red, green and blue phosphors to form a screen . An electron gun placed inside the tube, in its rear part, generates three electron beams in the direction of the front face. An electromagnetic deflection device, generally placed outside the tube and close to the electron gun, has the function of deflecting the electron beams in order to make them scan the surface of the panel on which the phosphor networks are arranged. Under the influence of three electron beams each corresponding to a given primary color, the phosphor networks allow the reproduction of images on the screen, the mask allowing each determined beam to illuminate only the phosphor of the corresponding color. The color selection mask must be placed and maintained during the operation of the tube in a precise position inside the latter. The mask holding functions are performed by means of a generally very rigid rectangular metal frame on which the mask is conventionally welded. The frame / mask assembly is mounted in the front face of the tube by means of suspension most often welded to the frame and cooperating with pins inserted in the glass constituting the front face of the tube.

The tubes whose front face is more and more flat correspond to the current trend, with an evolution towards totally front faces planar. To produce tubes comprising such a front face, it is a technology consisting in using a plane mask, kept in tension in at least one direction. Such structures are described for example in American patent US4827179. The color selection mask being constituted by a very thin metal sheet, parasitic phenomena of vibration of said mask can appear during the operation of the tube. Under the influence of shock or external mechanical vibrations, for example acoustic vibrations due to the loudspeakers of the television set in which the tube is inserted, the mask can enter into vibration according to its natural frequency of resonance. The vibrations of the mask have the consequence of modifying the landing zone of the electron beams on the screen of the tube, the points of impact of each beam then being offset with respect to the associated phosphor network, thus creating a discoloration of the image reproduced on the screen.

The masks adapted to the flat front faces have a central surface which is also substantially flat; in particular, in the case where the mask is kept in tension by the frame, it has a greater sensitivity to the vibrations of its environment necessitating the use of damping means to prevent the mask from entering into vibration.

These damping means generally comprise mobile parts capable of moving when the mask tends to vibrate connected by welding to the surface of the mask. These damping devices are particularly effective, but since they are arranged near the edges of the mask, they can become blocked on said edges if they start to vibrate with a very large amplitude.

The invention makes it possible to avoid this blockage and also makes it possible, among other advantages, to improve the dissipation of the energy generated by the vibrations of the mask.

For this, the cathode ray tube according to the invention comprises: a mask for selecting colors in the form of a substantially rectangular metal sheet, suitable for being fixed to a support frame and mounted inside the front face of the tube, said mask comprising a central zone pierced with orifices and a peripheral zone, arranged between the central zone and the edges of the mask

- means for damping vibrations of the mask arranged at said periphery of the mask to dampen the vibrations of said mask comprising a flexible metal strip characterized in that the metal strip has at least one zone whose width is greater than the width of the strip at its ends. The invention will be better understood with the aid of the description below and of the drawings, among which:

- Figure 1 shows a cathode ray tube according to the invention seen partially in exploded form - Figure 2 describes a frame / mask assembly stretched according to the state of the art with a vibration damper according to the state of the art.

FIGS. 3 and 4 show, in perspective and side views, a vibration damping device according to the state of the art. FIG. 5 shows an embodiment, in top view partially exploded, illustrating the principle of the invention

- Figure 6 shows the device of Figure 5 in a side view As illustrated in Figure 1, a cathode ray tube 1 according to the invention comprises a substantially flat slab 2 and a peripheral skirt 3. The slab is connected to the rear part of the tube, funnel-shaped 4 thanks to a sintered glass seal. The end portion of the tube 5 surrounds the electron gun 6 whose beams illuminate the screen of luminescent phosphors 13 through the color selection mask 8, for example stretched between the long sides 9 of the frame 19. Supports of the frame / mask assembly hold this assembly inside the tube, said supports being able to comprise a part 10 welded to the frame and a spring portion 11, provided with an opening to cooperate with a pin 12 included in the glass skirt 3. In the example of the prior art illustrated in FIG. 2, the frame 19 , comprises a pair of long sides 9 and a pair of short sides 7, said long and short sides having for example an L-shaped section. The mask 8, itself of substantially rectangular shape, is tensioned, then maintained in this state for example by welding on the end 20 of said long sides of the frame. The mask consists of a metal sheet, for example of steel or Invar, of very small thickness, of the order of 100 μm. The mask has a central zone 30 pierced with openings generally arranged in columns and a solid peripheral zone 28 surrounding the central zone with horizontal edges 31 and vertical edges 32. Cathode ray tube structures using a color selection mask have to face the vibration problem of this mask, according to their own modes, when said mask is excited by external vibrations, for example mechanical shocks on the tube or sound vibrations coming from loudspeakers arranged near the tube. These vibrations being manifested by movements of the mask in a direction perpendicular to its surface, the distance between the openings of the mask and the screen varies locally depending on the amplitude of the vibration of said mask. The purity of the colors reproduced on the screen is then no longer guaranteed, the landing points of the beams on the screen being shifted as a function of the amplitude of the vibration. Furthermore, as the mask is placed inside the tube in which there is a high vacuum, the vibrations of the mask are only very slowly absorbed, the energy communicated to the mask having few means of dissipation, which increases the visibility of the phenomenon on the screen when the tube is in operation. Figures 3 and 4 show in perspective and side views an example of vibration damper 55 according to the prior art, for a mask stretched in one direction, for example in the direction parallel to its short sides 32. In the peripheral part 28 of the mask 8, for example along its short vertical sides 32, is arranged a metal strip, comprising a central part 51 and two arms 53 extending on either side other of this central part, the strip is secured to the surface of the edge of the mask, for example by welding, either in its middle 51 or at its ends 52. In the case of FIG. 3 the strip is intended to be welded in its ends, this is why it is folded so that the U-shaped medium 51 comes to rest in contact with the surface of the mask. The damping device 55 will form with the mask a system of coupled oscillators; the parameters of the damping device 55 are chosen so that the natural frequency of vibration of the device 55 is close to a chosen value, for example the natural frequency of resonance of the mask so that the vibrations of the device d damping 55 is removed from the vibrations of the mask. The central part 51 is folded so as to come to rest in contact with the mask; in the case where the damping strip 55 is welded to the mask at its ends, the central part rubs against the surface of the latter when the mask vibrates to dissipate the vibration energy. In the case where the strip is welded to the mask in its middle 51, the ends 52 are folded so as to come into contact with the mask and rub against the surface of the latter when the mask is in vibration.

However, when the amplitude of the vibrations becomes very high, it can happen that the central part 51 or the ends 52 of the shock absorber passes on the other side of the edge of the mask and come to hang on the edge of the latter. The shock absorber thus immobilized no longer fulfills its function.

It can also happen that a part of the surface of the strip passes over the central surface of the mask, when the mask undergoes vibrations of significant amplitude and then comes to cause visible shadows on the screen of the tube.

FIG. 5 illustrates an embodiment of the invention avoiding the appearance of this problem. The principle of the invention is to increase the moment of inertia in rotation of the metal strip which amounts to increasing the lateral rigidity of said metal strip serving as a shock absorber, in order to avoid lateral displacements of the parts of said strip above the surface of the mask.

For this, the strip has a central zone 151 and two arms 153 extending on either side of the central zone. Each arm ends in an end 152 coming into contact with the surface of the mask. In order to increase the moment of inertia in rotation of the strip 155 and to increase the lateral mechanical rigidity, the width of the arms 153 increases from their end 152 towards the central part 151.

The strip 155 can be optionally secured to the surface of the mask either by welding in the middle 151 or by welding its ends 152. Preferably, the arm is widened towards the outside of the mask so as not to cover the central zone 30 of the mask. In this way, the longitudinal edge 156 of the strip 155, located closest to the central zone of the mask remains substantially parallel to the border between this central zone and the non-perforated zone 32. The mask generally comprises on its non-perforated part a or several orifices 170 intended to adjust parameters of orientation of the image during the final adjustment of the tube. In order to leave this or these orifices visible, the damping strip 155 comprises at least one notch 171 arranged so as not to conceal the orientation orifices 170 when said strip is secured to the surface of the mask.

In an advantageous embodiment, additional energy dissipation means 160 are arranged on the arms 153 allowing the mask to absorb more quickly.

As the mask is found inside the tube in a very high vacuum, it is sometimes necessary to add means of dissipation of energy so that the mask absorbs more quickly. It is for example advantageous to add to a metal strip 155 forming coupled oscillator, at least one metal collar 160 passing through an orifice 161 formed in said strip. The collar can be opened or closed, its section being slightly less than the diameter of the orifice 161 so as to be able to move in this orifice and dissipate the energy by friction on the edge of said orifice.

In another embodiment, not shown, rivets are arranged so as to pass through the metal strips 155 through orifices 161 formed thereon, the heads of the rivets having a dimension greater than that of the orifices while the body of the rivet has a section smaller than the diameter of said orifice.

Furthermore, the damping strips 155 can indifferently be placed on the surface of the mask facing the phosphor screen or vice versa on the surface of the mask on the electron gun side. It may also be advantageous to have the dampers 155 on both sides of the mask in order to obtain the desired damping effect. The invention and the means for dissipating the vibration energy described are suitable for all these different cases.

Claims

1 / Color cathode ray tube (1) comprising: a color selection mask (8) in the form of a substantially rectangular metal sheet, secured to a support frame (19) and mounted inside the front face of the tube, said mask comprising a central zone (30) pierced with orifices and a peripheral zone (28) disposed between the central zone and the edges of the mask of the vibration damping means of the mask arranged on at least one side of the mask , at its periphery, these means having the form of flexible metal strip (155) comprising a central part (151) and two arms (153) arranged on either side of the central part, characterized in that the metal strip has at the at least one zone (151, 153) whose width is greater than the width of the strip at its ends (152).

2 / cathode ray tube according to the preceding claim characterized in that the central area (151) of the metal strip is wider than its ends (152).

3 / cathode ray tube according to claim 1 characterized in that the width of the arms of the metal strip increases from their end (153) towards the central part (151)

4 / cathode ray tube according to claim 1 characterized in that the central zone of the metal strip is folded to come into contact with the surface of the mask 5 / Tube according to claim 1 characterized in that the metal strip (155) is welded to the surface of the mask at its central part (151).

6 / Tube according to claim 1 characterized in that the metal strip (155) is welded to the surface of the mask at its ends (152)

Il Cathode ray tube according to claim 1 characterized in that the metal strip further comprises energy dissipating means (160)

8 / cathode ray tube according to the preceding claim characterized in that the energy dissipating means comprise at least one ring passing through the thickness of the metal strip at the level of the arms (153).

9 / cathode ray tube according to claim 1 characterized in that the metal strip has at least one notch (171).