FR2654551A1 - Colour cathode-ray tube and magnetic screenings and frame installed in such a tube - Google Patents

Abstract

The invention relates to a colour cathode-ray tube and magnetic screenings and a frame installed in such a tube. This cathode-ray tube, including a neck (1a), a flared part (b) in the form of a truncated pyramid connected to the neck and a front display panel (1c) connected to the flared part and possessing a part forming a skirt extending along the axis of the tube, on the periphery of the panel, comprises a frame (5) arranged along the inner surface of the skirt-forming part in the direction of the axis of the tube, a perforated mask (4) mounted on the front of the frame (5), magnetic screening in the form of a strip (11 and/or 12) placed on the internal and/or external periphery of the frame. Application especially to colour television tubes.

Description

 The invention relates to a color cathode ray tube of the perforated mask type, and in particular to the external shielding structure vis-à-vis a magnetic field of a body forming the perforated mask.

 In a perforated mask-type color cathode ray tube, the electron beam emitted by an electron gun passes through a hole in the electron beam, which the perforated mask contains, and strikes the luminescent screen so as to bring the luminescent substance to produce fluorescence. The purpose of the shadow mask is to control the path of the electron beam and to cause the phosphor to selectively produce fluorescence.

 The perforated mask consists of a thin plate of iron or a ferrous alloy having a plurality of through holes for the passage of the electron beam and is mounted on a robust frame made of iron or ferrous alloy having an L-shaped cross-section. .

 The frame is supported by a plurality of springs at the skirt portion of the panel, which is a component of the tube.

 When the shadow mask or the frame is magnetized, the path of displacement of the electron beam varies, which causes disturbances, such as a color variation, which increases around the screen, mainly at the four levels. corners of the latter.

 Fig. 8, appended to the present application, is a sectional view showing the approximate structure of a known color perforated mask cathode ray tube.

 The tube 1 comprises the neck la, the funnel lb and the panel Ic.

 The electron gun 2 is installed in the neck la. Reference numeral 3 denotes a luminescent screen, in which the phosphor emitting red, green and blue lights is fixed in the manner of a mosaic on the inside of the panel 1c.

 The shadow mask 4 is formed of a thin plate and the holes 6 for the passage of the electron beam are formed in this plate according to a predetermined arrangement.

 The frame 5 is formed of a rectangular material having an L-shaped cross-section, which surrounds the periphery of the luminescent screen 3 and is arranged to be nested in the skirt portion of the panel 1c.

 The perimeter of the perforated mask 4 is fixed to the side wall 5a of the frame 5, which faces the skirt portion of the panel 1c, for example by welding.

 One end of each spring 7 is attached to the side wall 5a on each side so as to form part of a shadow mask body 20.

 Through holes (not shown) are formed at the other end of each spring 7 and are fitted on lugs (not shown) arranged on the inner face of each side of the skirt portion of the panel 1c so that the perforated mask 4 faces the luminescent screen 3, separated from it by a specified interval.

 The inner magnetic shield 8 is formed by a thin plate having a high permeability and arranged in the manner of a truncated pyramid extending along the funnel 1b, the periphery 8a of the front end of this shield being fixed , for example by welding, at the side 5b directed towards the electron gun 2 of the frame 5.

 The cross section ~ of the material constituting the frame 5 receives an L shape so as to confer the necessary mechanical strength to the material by reducing the length of the side wall 5a in the direction of the axis of the tube.

 By way of example, a description given in Japanese Patent Application Publication No. 31063/1985 will be given below.

 If the side wall 5a of the frame 5 extends beyond the end of the skirt portion of the panel 1c, the shadow mask body 20 is damaged in the manufacture of the color cathode ray tube. Therefore, in order to prevent any damage to this body, it is necessary to give an L shape to the cross section of the material constituting the frame in order to house the mask body 20 in the skirt portion of the panel 1c.

 The reference 9 designates a line representing the electron beam emitted by the electron gun 2 and which performs a scan in the zone represented by a dashed line, under the effect of a polarization applied by non polarization means. shown, and the electron beam 9 passing through the passage hole 6 provided for this beam strikes the luminescent screen so as to cause the portion that meets this electron beam on the phosphor, to selectively produce a fluorescence.

 In this case, if the color cathode ray tube is present in a magnetic field present in the environment, for example geomagnetism, the path of movement of the electron beam 9 is curved. The internal magnetic shielding 8 is used to suppress the influence of the magnetic field of the environment. Since the magnetic field of the environment is stopped and weakened in the tube enclosed in the internal magnetic shielding 8, the path of displacement of the electron beam 9 is only slightly curved, the distance from the impact position of the electron beam 9 on the luminescent screen 3 decreases and the color distortion is reduced. However, since the shadow mask 4 is magnetized by the magnetic field of the environment, the effect of magnetism protection by the internal magnetic shielding 8 is limited.

 Hereinafter, the color distortion caused by the magnetic shadow mask will be described in detail.

 Figure 10, appended to the present application, shows the state of the magnetic flux 10 when the shadow mask body 20 is placed in the magnetic field of the environment, parallel to the direction of the magnetic field.

 The perforated mask 4 and the frame 5 are made of iron or a ferrous alloy and are magnetized by the magnetic field of the environment, and the magnetic flux 10 shown in FIG. 11 is present at the hole 6 of the beam passing through. electrons, formed in the perforated mask 4.

 It is generally known that electrons penetrating into a magnetic field of uniform intensity, perpendicular to the direction of this field, move in a circular orbit under the effect of the Lorentz force.

 Figure 12, appended to the present application, shows the state of the electrons indicated above. In this case, although the effective direction, in which the electron beam 9 is curved, is perpendicular to the surface of the paper, this direction has been drawn as if it were parallel to the surface of the paper, so that can easily understand the path of displacement of the electron beam 9 and the distribution of the magnetic field.

If an electron penetrates vertically into a magnetic field of uniform intensity of length "1" and moves at a speed "v", the deviation "d" of electron beam 9 is provided by the following relation (1)
eH d = ~~~~~~ units 2
2cmv with E: intensity of the magnetic field in hole 6 of the passage
electron beam, e: electric charge of the electron, m: mass of the electron, c: electromagnetic constant.

From the expression (1), we see that the deviation (d) of the path of the electron beam is proportional to the intensity of the magnetic field and to the square of the length g
Therefore, if the intensity "H" of the magnetic field in the electron beam-passing hole 6 increases, a correct color image can not be obtained due to the color distortion, since the deviation " d "of the electron beam 9 increases as shown in FIG. 13 and that the electron beam 9 encounters the phosphor 3b situated in a position different from that of the phosphor 3a, which should have been initially encountered electron beam 9.

 Moreover, the existing internal magnetic field 8 is fixed on the side 5b of the frame 5, located opposite the L-shape, for example by a weld, and this seal has a high magnetic resistance. Therefore, as the leakage flux increases, the color distortion increases around the screen, mainly at the four corners of the screen.

 We will give the following reason.

 Figure 14, appended to the present application, shows the state of the magnetic flux 10 when the shadow mask body 20 is placed in the magnetic field of the environment, perpendicular to the direction of this magnetic field.

 The magnetic flux 10 passes through the perforated mask 4 and the frame 5. However, the magnetic flux penetrating through the side wall 5a has the complex distribution shown in FIG. 14 since it passes through the opposite face 5b and leaves at the end of FIG. this face to enter the tube.

 Therefore, the point of impact of the electron beam 9, which passes through this zone to reach the luminescent screen 3, on this screen is deflected, resulting in color distortion since the path of movement of the beam is disturbed when passing through the area.

 In addition, the existing frame 5 has a high magnetic resistance since it can not have a sufficiently long side wall 5a since the height of the skirt portion of the panel is limited.

 That is, although the inner magnetic shield 8 is mounted on the opposite face 5b, the magnetic flux 10 does not penetrate the inner magnetic shield 8 from the side wall 5a, but passes through the opposite side. 5b and out through the end of this face, since the junction between the frame 5 and the inner magnetic shield 8 has a high magnetic resistance.

 This is why, in practice, the length of the magnetic path passing through the side wall 5a of the frame 5 is not increased.

 As a result, as shown in FIG. 14, the magnetic flux penetrating the peripheral zone of the perforated mask 4 increases and the intensity of the magnetic field in the electron beam passing hole 6 in this zone increases, which increases the color distortion.

 As mentioned above, for the existing shadow mask body 20, in which an L-shaped frame is used, the inner magnetic field is distributed in the peripheral area and the magnetic field strength in the beam through hole. electrons in the peripheral area increases. Therefore, the existing shadow mask body having a t-shaped frame has the disadvantage that the color distortion increases at the peripheral area of the screen, mainly at the four corners of the screen.

 The object of the present invention is to solve the problem indicated above and to make a color cathode ray tube making it possible to reduce the color distortion on a screen, this color distortion being due to a magnetic field of the environment such as, for example geomagnetism, and mainly to reduce the color distortion at the four corners of the screen.

 According to a first aspect of the invention, this problem is solved by means of a color cathode ray tube comprising a neck, a truncated pyramidal funnel connected to the neck, and a front display panel connected to the wall. funnel and having a skirt-shaped portion extending along the axis of the tube, on the periphery of the panel, characterized in that it comprises a frame installed along the inner face of the skirt portion and extending in the direction of the axis of the tube, a perforated mask mounted on the front part of the frame, and a strip-shaped magnetic shield installed along the inner periphery of said frame.

 According to another aspect of the invention, this problem is solved using a color cathode ray tube having a neck, a truncated pyramid funnel connected to the neck, and a front display panel connected to the funnel and having a skirt-shaped portion extending along the axis of the tube, on the periphery of the panel, characterized in that it comprises a frame installed along the inner face of the skirt portion and s extending in the direction of the axis of the tube, a perforated mask mounted on the front part of the frame, a first band-shaped magnetic shield installed along the inner periphery of said frame, and a second band-shaped magnetic shield installed along the outer periphery of said frame.

 The first and second magnetic shields reduce color distortion by inducing the magnetic flux of the magnetic field of the environment and reducing the intensity of the magnetic flux penetrating the perimeter of the shadow mask, the magnetism of this shadow mask and the magnetic field. located in a passage hole of the electron beam.

 According to another aspect of the invention, there is provided a color cathode ray tube having a neck, a truncated pyramid funnel connected to the neck, and a front display panel connected to the funnel and having a shaped portion. skirt extending along the axis of the tube, on the periphery of the panel, characterized in that it comprises a frame having a side wall disposed along the inner face of the skirt portion and extending into the direction of the tube axis, and an extended pyramid-shaped side formed between the side wall and the funnel, a perforated mask mounted on the front of the frame, and a trunk-shaped internal magnetic shielding pyramid, connected to the rear end of the extended side of said frame and extending along the inner surface of said funnel. Since the magnetic flux produced by the magnetic field of the environment in the peripheral zone of the shadow mask is induced in the frame and is sent to the inner magnetic shield, the intensity of the magnetic flux entering the tube is reduced. Since the magnetic resistance of the frame is reduced, the magnetic field in the passage hole of the electron beam in the peripheral area of the shadow mask is reduced. Then the color distortion at the peripheral area of the screen, especially at the four corners of the latter, is reduced.

Other features and advantages of the present invention will emerge from the following description given with reference to the accompanying drawings, in which:
Fig. 1 shows an exploded perspective view of the color cathode ray tube corresponding to an embodiment of the present invention;
FIG. 2 is a perspective view partly on a larger scale of the shadow mask body of the embodiment of FIG. 1;
FIG. 3 represents the state of the magnetic flux when the shadow mask body corresponding to the embodiment of FIGS. 1 and 2 is arranged parallel to the magnetic field of the environment;
FIGS. 4 and 5 show the state of the magnetic flux obtained when the shadow mask bodies of other embodiments of the present invention are arranged parallel to the magnetic field of the environment;
FIG. 6 represents an exploded perspective view of an alternative embodiment of the invention;
FIG. 7 represents the state of the magnetic flux when the shadow mask body of the embodiment according to the invention is arranged perpendicularly to the magnetic field of the environment;
FIG. 8 represents a sectional view of the approximate structure of an existing color cathode ray tube;
FIG. 9 represents a front view, partly on a larger scale, of the perforated mask;
FIG. 10 represents the state of the magnetic flux when the existing shadow mask body is disposed parallel to the direction of the magnetic field of the environment;
FIG. 11 represents the distribution of the magnetic flux around the passage hole of the electron beam, which comprises the existing shadow mask body;
FIG. 12 represents a sectional view showing the distribution of the magnetic flux and the deviation of the magnetic beam at the level of section XII-XII of FIG. 11;
FIG. 13 represents an approximate sectional view illustrating the modification of the path of displacement of the electron beam; and
Fig. 14 is a diagram showing the distribution of the magnetic flux when a shadow mask body of an existing inner magnetic shield is disposed perpendicular to the direction of the magnetic field of the environment.

 Fig. 1 shows a partial perspective view of an embodiment of the present invention.

 Fig. 2 shows a partial perspective view, partly on a larger scale, of the shadow mask body 20 of the embodiment of the invention.

 The reference 11 designates the first band-shaped shield, which is installed on the inner periphery of the side wall 5a of the frame 5 and is fixed to this side wall 5a for example by welding.

 Reference numeral 12 designates the second band-shaped shield, which is installed along the outer periphery of the side wall 7a and is fixed to the frame 5 in the same manner as the first shield 11. The first and second shields 11 and 12 are installed directly against the frame 5, produce a high magnetic resistance and are made of a magnetic material having a permeability greater than that of the frame 5, for example a Ni-Fe alloy (trademark: PERMALLOY).

 Organic compounds such as, for example, an epoxy adhesive can be used to connect elements having a high magnetic resistance.

 The effects produced by the first shield 11 and the second shield 12 will be described below.

 FIG. 3 shows the state of the magnetic flux obtained when the shadow mask body 20 of the embodiment of the invention is placed in the magnetic field of the environment, parallel to the direction of this field.

 The magnetic flux penetrating the second shield 12 at the periphery passes through this shield. However, part of the magnetic flux 10 comes out and enters the frame 5 in the form of a leakage flux.

 The magnetic flux 10, which escapes from the frame 5, passes through the first shield 11 at the inner periphery to enter the frame 5 again and passes through the second shield 12 to exit the tube. In this case, since the first shield 11 and the second shield 12 are connected to the frame 5 in the state where they provide a high magnetic resistance and are made of a material having a high permeability, the magnetic flux 10 easily penetrates into the first shield 11 and in the second shield 12, producing an intense magnetic protection effect.

 Therefore, the screen 5, the first shield 11 and the second shield 12 have a triple role of protection vis-à-vis the magnetism. This is why the magnetic flux penetrating the perforated mask 4 and the magnetism of this perforated mask are reduced.

 Since the hole 6 of passage of the electron beam, which comprises the perforated mask 4, has a diameter of between 0.1 and 0.2 mm, it is difficult to directly measure the intensity of the magnetic field in the hole. 6 of passage of the electron beam. As a result, the intensity is measured using a larger model of the same material.

 As a result, the maximum intensity of the magnetic field in the electron beam passing hole 6 for the magnetic field intensity of the environment equal to 79.58 / enz becomes equal to 71.62 in this form of This leads to a reduction in the approximate ratio 1/7, although the maximum intensity of the magnetic field is equal to 477.48 / enz for the existing mask body 20.

 Likewise, the distance of the electron beam 9 on the luminescent screen 3 is reduced in the approximate ratio 1/7, as revealed by the measurement carried out with a real color cathode ray tube.

 Said embodiment represents the case where the first shield 11 and the second shield 12 are installed respectively on the inner periphery and on the outer periphery of the frame 5. However, even if only one or the other of these shields is installed. a similar effect is obtained, although less than that obtained in said embodiment.

 FIG. 4 shows the state of the magnetic flux when the mask body 20 having only the first inner shield 11 is placed in the magnetic field of the environment, parallel to the direction of this field.

 FIG. 5 represents the state of the magnetic flux, when the mask body 20 having only the second external field 12 is placed in the magnetic field of the environment, parallel to the direction of this field.

 In all cases, the frame 5 and the first shield 11 or the second shield 12 provide a double protection against magnetism. That is why the distance of the electron beam 9 on the luminescent screen 3 is reduced in the ratio equal to about 1/6 for the embodiment of FIG. 4 and in the ratio equal to about 1/4 for the embodiment of Figure 5, with respect to the gap obtained in existing embodiments.

 FIG. 6 shows an exploded perspective view of another embodiment of the present invention, in which the frame 5 is formed of a material having a permeability greater than that of the shadow mask 4 and comprises the side wall 5 and the extended side 5c made in the manner of a truncated pyramid extending from the side wall 5a, and the front end of the inner magnetic shielding 8 is connected to the inner end of the extended side 5c, by means of a link having a low magnetic resistance, for example by welding.

 PERMALLOY is used as material constituting frame 5.

 Fig. 7 shows the state of the magnetic flux obtained when the shadow mask body of this embodiment is placed in the magnetic field of the environment, perpendicular to the direction of the magnetic field. In Figure 7, the magnetic resistance is reduced since the length of the side wall 5a of the frame 5 is effectively reduced and that frame is made of a material having a high permeability. Therefore the magnetic flux in the peripheral area of the shadow mask 4 penetrates the side wall 5a and reaches the inner magnetic shield 8 through the extended face 5c.

 Consequently, the magnetic flux penetrating the perforated mask 4 decreases and the magnetic field is not disturbed in the peripheral zone of the shadow mask 4, unlike the existing embodiments.

 Therefore, since the intensity of the magnetic field in the electron beam-passing hole 6 and the electron beam deflection 9 decrease, the color distortion at the periphery of a screen, mainly at the level of the four corners of this screen, is reduced.

 Although the extended face 5c protrudes from the skirt portion of the panel, the problem mentioned in Japanese Patent Publication No. 31063/1985 does not occur because the manufacturing process is automated.

Claims (12)

 1. Color cathode ray tube having a neck (la), pyramid-shaped funnel (lb) connected to the neck, and a front display panel (tic) connected to the funnel and having a skirt-shaped portion extending along the axis of the tube, on the periphery of the panel, characterized in that it comprises a frame (5) installed along the inner face of the skirt portion and extending in the direction of the axis of the tube, a shadow mask (4) mounted on the front part of the frame (5), and a strip-shaped magnetic shield (11) installed along the inner periphery of said frame.  2. Band-shaped magnetic shielding used in the device according to claim 1, characterized in that it is made of a material having a magnetic permeability greater than that of said frame (5).  3. Band-shaped magnetic shielding used in the device according to claim 1, characterized in that it is connected to the frame (5) by a connection having a high magnetic resistance.  4. Color cathode ray tube having a neck (la), pyramid-shaped funnel (lb) connected to the neck, and a front display (tic) connected to the funnel and having a skirt-shaped portion extending along the axis of the tube, on the periphery of the panel, characterized in that it comprises a frame (5) installed along the inner face of the skirt portion and extending in the direction of the axis of the tube, a perforated mask (4) mounted on the front part of the frame (5), and a strip-shaped magnetic shield (12) installed along the outer periphery of said frame.  Band-shaped magnetic shielding used in the device according to claim 4, characterized in that it is made of a material having a magnetic permeability greater than that of said frame (5).  6. Band-shaped magnetic shielding used in the device according to claim 4, characterized in that it is connected to the frame (5) by a connection having a high magnetic resistance.  7. Color cathode ray tube having a neck (la), a pyramid-shaped funnel (1b) connected to the neck, and a front display panel (1c) connected to the funnel and having a skirt-shaped portion extending along the axis of the tube, on the periphery of the panel, characterized in that it comprises a frame (5) installed along the inner face of the skirt portion and extending in the direction of the axis of the tube, a perforated mask (4) mounted on the front part of the frame (5), and a first band-shaped magnetic shield (11) installed along the inner periphery of said frame, and a second magnetic shield in band form (12) installed along the outer periphery of said frame.  8. Magnetic shields in the form of strips used in the device according to claim 7, characterized in that they are made of a material having a magnetic permeability greater than that of said frame (5).  9. Magnetic shields in the form of strips used in the device according to claim 7, characterized in that they are connected to the frame - (5) by a connection having a high magnetic resistance.  10. Color cathode ray tube having a neck (la), pyramid-shaped funnel (1b) connected to the neck, and a funnel-shaped front display panel (1c) having a shaped portion skirt extending along the axis of the tube, on the periphery of the panel, characterized in that it comprises a frame (5) having a side wall (5a) arranged along the inner face of the skirt portion and extending in the direction of the axis of the tube, and a pyramid-shaped extended side (5c) formed between the side wall (5a) and the funnel (1b), a perforated mask (4) mounted on the front of the frame (5), and a pyramid-shaped inner magnetic shield (8) connected to the rear end of the extended side (5c) of said frame (5) and extending along the inner surface of said funnel (1b).  11. Internal magnetic shielding used in the device according to claim 10, characterized in that it is connected to the rear end of the extended side (5a) of said frame (5) in a connection having a low magnetic resistance.  12. Frame used in the device according to claim 11, characterized in that it is made of a material having a magnetic permeability greater than that of the perforated mask (4).