JPH0737228Y2 - Color cathode ray tube - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application] The present invention relates to a color cathode ray tube having a magnetic shield.

[Conventional technology]

In general, during operation of a color cathode ray tube, the electron beam is in addition to the magnetic field of the deflection yoke, an external stray magnetic field, such as
Under the influence of terrestrial magnetism and unnecessary magnetic fields generated from electronic circuits built into television receivers, erroneous deflection operation is performed, causing undesired phosphors to emit light, resulting in unfavorable results such as reduced color purity. Invited. In order to eliminate the influence of such an external stray magnetic field, an external magnetic shield that normally surrounds the outer periphery of the funnel of the color cathode ray tube is provided, or the funnel of the color cathode ray tube is used to improve the shielding effect. An internal magnetic shield was provided inside, or an external magnetic shield and an internal magnetic shield were provided side by side to maximize the shield effect.

Among such conventional color cathode ray tubes, a color cathode ray tube provided with an inner magnetic shield and an outer magnetic shield will be described with reference to the drawings. In FIG. 5, (1)
Is a tube body of a color cathode ray tube, which has a panel portion (1a) having a fluorescent surface (9) formed on the inner surface thereof, and a funnel portion (1b) welded to the outer peripheral edge of the panel portion (1a) by using, for example, fritted glass. ) And a neck portion (1c) formed integrally with the funnel portion (1b). (2) is an aperture mask, which has a large number of pores (10) formed in a fixed pattern, faces the fluorescent surface (9) of the panel portion (1a), and keeps a predetermined gap (20). The color cathode ray tube has a color selection function. (3) is an annular frame, which is made of a magnetic metal material having a plate thickness of 1 to 2 mm and holds the aperture mask (2) at its peripheral edge. (4) is a support member formed of a plate-like elastic member, one end of which is fixed to the frame (3) and the other end of which is a pin (not shown) that is erected on the side wall of the panel portion (1a). Fit and hold the aperture mask (2) in place within the tube (1). (5)
Is an internal magnetic shield arranged along the inner surface of the funnel part (1b), and is formed by a magnetic metal plate with a thickness of 0.1 to 0.2 mm so as to cover the traveling path of the electron beam (8). The part is fixedly held on the frame (3).
(7) is an external magnetic shield, which is made of a magnetic metal plate and is formed in a shape surrounding the outer peripheral surface of the funnel portion (1b).

When the color cathode ray tube configured as described above is operated,
An electron beam (8) emitted from an electron gun housed in the neck portion (1c) passes through the pores (10) of the aperture mask (2) and a fluorescent surface (9) formed on the panel portion (1a). ) To cause the fluorescent surface (9) to emit light. Here, according to FIG. 6, when the color cathode ray tube is installed facing the respective directions of east (E), west (W), south (S), and north (N), the fluorescent surface of the electron beam (8). (9) The influence (deflection) of the projecting point above due to the presence of geomagnetism will be described.

In FIG. 6, (9) is the fluorescent surface viewed from the panel portion (1a) side, (a) to (i) are the respective representative projecting points of the electron beam (8) in the absence of geomagnetism, that is, This is a desirable point that the electron beam should originally strike. Each point (a) above
The vectors indicated by the symbols E, W, S, N from (i) are the above points (a) when the color cathode ray tubes are installed in the east, west, south, and north directions, respectively. The electron beam (8) to be projected on each of (i) to (i) shows the direction and size of movement under the influence of geomagnetism. As you know,
Since the S pole as a magnet exists near the north pole of the earth and the N pole exists near the south pole, a geomagnetic field exists from the south to the north.

Therefore, as shown in FIG. 6, the direction of the magnetic field of the geomagnetism with respect to the fluorescent surface (9) is as follows: when the color cathode ray tube is installed in the east direction, the arrow E direction (the right direction on the paper), the west direction,
Arrow W direction (left side of paper), when facing south, S direction (direction perpendicular to paper), when facing north, The direction is N (perpendicular to the paper surface). Also, the electron beam (8) is directed to the center point of the fluorescent surface (9), that is, the point (e).
From the electron gun placed on the vertical line from, the fluorescent surface (9)
It is emitted toward and is deflected by the magnetic field of the deflection yoke to horizontally scan the fluorescent surface (9) and vertically scan the entire surface, which is clear from Fleming's left-hand rule. , The electron beam (8) moves in the vector direction shown in FIG. That is, when the color cathode ray tube is installed in the east or west direction, the electron beam (8) moves in the vertical direction of the fluorescent surface (9), and when installed in the south or north direction, Move in the direction shown in the figure to the tangential direction of the circle centered on (e).

FIG. 7 is a partially enlarged view of the stripe-shaped fluorescent surface (9). (B) is a blue fluorescent substance row, (R) is a red fluorescent substance row,
(G) is a green phosphor array. Aperture mask (2)
The pores (10) formed in correspond to the set of phosphor rows (B), (R), (G), respectively, and the electron beam (8) emitted from the electron gun is It passes through the pores (10) of the aperture mask (2) and strikes the corresponding row of phosphors (B), (R) or (G) to emit a desired color.

However, in a color cathode ray tube having such a stripe-shaped fluorescent surface (9), as shown in FIG.
Even if each electron beam (8) is affected by the geomagnetism and moves in the vertical direction, the electron beams (8) are inevitably collided with the fluorescent substance row of the same color.
It does not lower the color purity. Therefore, when the color cathode ray tube is installed facing east or west,
The effect of geomagnetism can be ignored. However, when the color cathode ray tube is installed facing south or north, the electron beam (8) moves left and right on the fluorescent surface (9) under the influence of the earth's magnetism. The color purity is lowered because it falls off from the light train or collides with another train of fluorophores. The outer shield (7) and the inner shield (5) are provided to prevent such a decrease in color purity.

FIG. 8 is a cross-sectional view of essential parts showing a distribution state of magnetic flux when a conventional type color cathode ray tube is installed facing south or north. As is clear from the figure, when a magnetic field in the tube axis direction is applied by geomagnetism, the magnetic flux (11) flows through the internal magnetic shield (5) and the external magnetic shield (7) having a small magnetic resistance, The influence on the beam (8) can be suppressed.

However, the magnetic flux (11) flowing inside the internal magnetic shield (5)
Are emitted as magnetic flux (12b) from the end of the frame (3). Since there is no magnetic shield in the gap (20) between the fluorescent surface (9) of the panel (1a) and the aperture mask (2), a part of the magnetic flux (12b) is generated by the aperture mask (2). The electron beam (8) passing through the peripheral pores (10) is greatly affected and the color purity is reduced.

Recently, the size of the color cathode ray tube has become larger and the length of the gap (20) has become larger. For example, in the case of a 28-inch, 110-degree deflecting color cathode ray tube having a fluorescent surface (9) of a substantially rectangular shape, the gap When Q is 25 mm, in this example, as shown in FIG. 9, the movement error of the electron beam (8) on the fluorescent surface (9) is 70 μm, and the color purity is lowered. Where the ninth
The horizontal axis of the figure is the length Q of the gap (20) between the fluorescent surface (9) and the aperture mask (2), and the vertical axis is the fluorescence when the color cathode ray tube is installed in the south or north direction. The movement amount of the electron beam on the surface (9) is shown. To prevent deterioration of color purity,
Considering the variation in the length Q of the clearance Q (20) in manufacturing, it is necessary to set the average amount of movement of the electron beam to 30 μm or less.

[Problems to be solved by the invention]

The present invention has been made in view of the above problems, and an object thereof is to obtain a color cathode ray tube which does not cause deterioration of color purity due to an external stray magnetic field.

[Means for solving problems]

The color cathode ray tube according to the present invention has a color cathode ray tube having an inner magnetic shield arranged along the inner surface of the funnel portion of the tube body and an outer magnetic shield arranged so as to surround the outer peripheral portion of the funnel portion. In the above, the external magnetic shield is formed so as to project at least 10 mm or more from the front surface of the panel portion following the funnel portion of the tubular body so as to integrally surround from the funnel portion to the front of the panel portion.

[Action]

The color cathode ray tube according to this invention has an external magnetic shield part that covers most of the magnetic flux emitted from the front end of the frame holding the aperture mask at its peripheral end and covers the gap between the aperture mask and the fluorescent surface of the panel part. By passing
The magnetic flux emitted from the front end of the external magnetic shield projecting forward from the front surface of the panel portion and leaking to the peripheral portion of the aperture mask is reduced. The influence of the external stray magnetic field on the electron beam is reduced, and the deterioration of color purity is suppressed.

An embodiment of the present invention will be described below with reference to the drawings.

1 differs from the conventional example shown in FIG. 5 in that an external magnetic shield (7) is provided with an aperture mask (2),
An external magnetic shield extension (7a) for magnetically shielding the gap (20) between the panel portion (1a) and the fluorescent surface (9) is provided, and the external magnetic shield extension (7a) is provided. It is to be projected 10 mm or more from the front surface of the panel part (1a). The operation of the magnetic shield extension portion (7a) will be described with reference to FIG. FIG. 2 is a sectional view of an essential part showing a magnetic flux distribution state when this embodiment is installed facing south or north. As shown in the figure, when a tube axis magnetic field is applied, its magnetic flux (11) flows through parallel magnetic paths that pass through the outer magnetic shield (7), the inner magnetic shield (5) and the frame (3). Is the same as the conventional one, but since the extension portion (7a) is formed in the external magnetic shield (7), the magnetic field lines (12a) flowing through the external magnetic shield (7) remain the extension portion (7a). Is discharged from its tip through Also, the magnetic field lines (12b) flowing through the internal magnetic shield (5)
Is emitted from the front end of the frame (3), but the magnetic resistance of the gap (20) between the aperture mask (2) and the fluorescent surface (9) of the panel portion (1a) is very large, so that The part is the extension part (7) of the external magnetic shield (7) with low magnetic resistance.
It enters into a) and is discharged from the front end of the extension part (7a). Therefore, of the magnetic field lines (12b) emitted from the front end of the frame (3), the number of magnetic field lines entering the peripheral portion of the aperture mask (2) can be extremely reduced, so that reduction in color purity is reduced. be able to.

In order to actually observe the effect of the earth's magnetism, when the 28-inch, 110-degree deflection color cathode ray tube is installed facing north and south, of the amount of movement of the electron beam, each phosphor array (B) , (R) and (G), only the components orthogonal to each other are shown and their magnitudes are shown in FIG. FIG. 10 shows the upper right part which is 1/4 of the fluorescent surface (9) shown in FIG. 6, and is (b), (c), (e),
(F), (j), (k) are the respective representative projecting points of the electron beam in the absence of geomagnetism, (b ₁ ), (c ₁ ), (f ₁ ),
(J ₁ ) and (k ₁ ) are the central points (e) of the fluorescent surface (9), respectively.
And each projecting point (b), (c), (f), (j), (k)
Is the midpoint between. The amount of movement of the electron beam at each of the above-mentioned points is the measured value of the conventional color cathode ray tube shown in FIG. 5 and the color cathode ray tube of the embodiment in which the extending portion shown in FIG. 1 is extended 10 mm before the front surface of the panel. Shown in the table below.

As is apparent from this table, in this embodiment, the amount of movement of the electron beam is reduced to about 40% of that in the conventional example, and it is understood that an extremely large shield effect is obtained. Further, a length L protruding forward from the panel front surface of the extending portion (7a),
FIG. 3 shows the result of an experiment conducted on the relationship of the amount of movement of the electron beam by using a color cathode ray tube of 28 inches and a deflection of 110 degrees.
Here, the horizontal axis of FIG. 3 is the length L protruding from the front surface of the panel, and the vertical axis is the diagonal portion (the first horizontal axis) having the largest movement amount on the fluorescent surface when the color cathode ray tube is placed in the north-south direction. The amount of movement of the electron beam at point (c) in FIG. 10 is shown. From this figure, it can be seen that the protrusion amount L is within a practical range of 10 to 50 mm. The amount of movement of the electron beam at the points on the fluorescent surface (9) other than the points shown in FIG. 10 is the same as the value at each symmetrical position shown in FIG.

FIG. 4 is a sectional view showing another embodiment of the present invention. In the figure, the difference from the embodiment of FIG. 2 is that the tip of the extending portion (7a) is bent outward at a substantially right angle to form a flange-shaped folded-back portion (7b).
Since this embodiment has the same effect as increasing the protrusion length L, it is effective when applied to the case where the protrusion length L cannot be increased.

[Effect of device]

As described above, according to the color cathode ray tube of the present invention, the external magnetic shield is provided at least from the front surface of the panel portion.
By projecting 10 mm or more and integrally surrounding the front part of the funnel part to the front part of the panel part, most of the magnetic flux that flows through the internal magnetic shield and is emitted from the frame on the peripheral edge of the aperture mask has a small magnetic resistance, That is, lead to the external magnetic shield side, and move 10 mm forward from the front of the panel.
It is possible to emit from the front end of the external magnetic shield separated from the above. Therefore, the effect of the external stray magnetic field such as the earth's magnetic field on the electron beam can be effectively suppressed by the synergistic action of both the inner and outer magnetic shields, and the deterioration of the color purity can be reliably stopped (stopped) within the practical allowable range. It has the effect of being able to.

[Brief description of drawings]

FIG. 1 is a partially cutaway side view of an embodiment of the present invention, and FIG.
FIG. 4 is a sectional view of a main part showing the magnetic flux distribution of this embodiment, FIG. 3 is a characteristic view showing the magnetic shield effect of this embodiment, and FIG.
FIG. 5 is a sectional view of a main part showing a magnetic flux distribution of another embodiment of the present invention. FIG. 5 is a partially cutaway side view of a conventional color cathode ray tube.
FIG. 6 is a front view of a fluorescent surface for explaining the influence of geomagnetism on an electron beam, FIG. 7 is a partially enlarged view showing the structure of a striped fluorescent surface, and FIG. 8 is a conventional color cathode ray tube. Fig. 9 is a cross-sectional view of the main part showing the magnetic flux distribution, Fig. 9 shows the relationship between the gap length of a conventional color cathode ray tube and the amount of movement of the electron beam projecting point on the fluorescent surface, and Fig. 10 shows the effect of geomagnetism. FIG. 6 is a diagram for explaining movement of a projecting point of an electron beam due to. (1) ... Tube body of color cathode ray tube, (1a) ... Panel section,
(1b) ... Funnel part, (5) ... Internal magnetic shield,
(7) ... External magnetic shield, (7a) ... Magnetic shield extension part, (7b) ... folded part. In the drawings, the same reference numerals indicate the same or corresponding parts.

Claims (2)

[Scope of utility model registration request] 1. A color cathode ray tube having an inner magnetic shield arranged along an inner surface of a funnel portion of a tubular body, and an outer magnetic shield arranged so as to surround an outer peripheral portion of the funnel portion, wherein The magnetic shield is projected at least 10 mm or more from the front surface of the panel part that follows the funnel part of the tube body,
A color cathode ray tube, characterized in that it has a shape that integrally surrounds from the funnel portion to the front of the panel portion. 2. The color cathode ray tube according to claim 1, wherein the outer magnetic shield is formed in a flange shape with its front end portion bent outward.