JP3034906B2 - Color picture tube and deflection device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention improves color aberration caused by a deflection magnetic field of a deflection device and improves focus characteristics, and a color picture tube and its deflection device. About.

(Prior Art) Generally, as shown in FIG. 13, a color picture tube comprises an envelope (3) composed of a panel (1) and a funnel (2).
The panel (1) faces the shadow mask (4) having a large number of electron beam passage holes formed therein, and emits blue, green, and red light on the inner surface of the panel (1). A phosphor screen (5) comprising a color phosphor layer is formed. An electron gun assembly (7) for emitting three electron beams (B), (G), and (R) is disposed in a neck (6) of the funnel (2), and emitted from the electron gun assembly (7). The three electron beams (B), (G), and (R) are horizontal and vertical by a deflection device (9) mounted outside the boundary between the cone (8) and the neck (6) of the funnel (2). By deflecting in the direction and scanning the phosphor screen (5), a color image is displayed on the phosphor screen (5).

As shown in FIG. 14, the deflecting device (9) includes a pair of horizontal deflecting coils (1) for deflecting the three electron beams in the horizontal direction.
0) and a pair of vertical deflection coils (1
1) and

In the color picture tube, a phosphor screen (5)
In order to display a correct image on the phosphor screen (5), three electron beams (B), (G),
It is necessary to correctly concentrate (R). Therefore, in particular, the electron gun assembly (7) is arranged in three rows in a row arranged on the same plane including the center beam (G) and the pair of side beams (B) and (R).
An in-line type electron gun structure that emits (R), and by taking advantage of the characteristics of the in-line type electron gun structure, the deflection magnetic field formed by the deflecting device (9) is set to a specific non-uniform magnetic field. 5) There is a self-convergence type in-line color picture tube in which three electron beams (B), (G) and (R) are concentrated over the entire surface. As the deflection magnetic field of the self-convergence type in-line type color picture tube, for example, three electron beams (B), (G),
It is known that a color picture tube that emits (R) includes a pincushion-type horizontal deflection magnetic field and a barrel-type vertical deflection magnetic field. With such a magnetic field, the three electron beams (B), (G), and (R) arranged in a line passing on the same horizontal plane can be concentrated at one point on the phosphor screen (5).

However, even if the magnetic field is configured as described above, the inline type color picture tube still generates coma aberration in which the convergence of the center beam (G) and the side beams (B) and (R) is shifted in the peripheral portion of the screen. .

In order to correct this coma, a magnetic body that couples to the rear leakage magnetic field of the deflection device is arranged in the electron gun structure.
JP-B-51-26208 and JP-B-54-23208 also disclose, without using a magnetic body that couples to the rear leakage magnetic field of such a deflection device, on the electron gun assembly side with respect to the deflection device. Japanese Utility Model Publication No. 57-45748 discloses an apparatus in which an auxiliary coil for forming a strong pincushion-type magnetic field by supplying a current synchronized with a deflection current flowing in a vertical deflection coil is added.

However, even when the color picture tube is configured in this manner, the spot of the electron beam on the phosphor screen is still distorted according to the deflection. That is, as shown in FIG. 15, the spot (13) of the electron beam deflected by the uniform magnetic field becomes almost a perfect circle over the entire screen (14), but as shown in FIG. At the horizontal axis (X-axis) end of the screen (14), the electron beam spot (13) is deflected by the pincushion-type horizontal deflection magnetic field (15) as shown in FIG. The beams (B), (G), and (R) are distorted into a horizontally long elliptical shape having a long axis in the horizontal axis direction due to the Lorentz force pressing the upper half downward and the lower half upward. At the end of the vertical axis (Y axis) of the screen (14), the electron beams (B), (G), (R) are formed by the barrel-type vertical deflection magnetic field (16) as shown in FIG. ) Is subjected to Lorentz force that pushes the right half to the right and the left half to the left, and is distorted into a horizontally long ellipse with the long axis in the horizontal axis direction. In particular, for the pair of side beams (B) and (R), the magnitude of the force received on the left and right sides of the beam is different, and the force received by the electron beam (B) on the left side of the screen and the electron beam (R) on the right side Are opposite, the spots of the pair of side beams (B) and (R) at the vertical axis end are shown in FIG. 16 as (13B) and (13).
Incline in the direction crossing each other as shown in R). As a result, due to the deformation or inclination of the beam spot caused by the horizontal or vertical deflection magnetic fields (15) and (16), the focus characteristic at the periphery of the screen (14) is significantly deteriorated. Moreover,
The deterioration of the focus characteristic is a major factor that hinders the performance enhancement of the electron gun structure.

Therefore, in order to improve the focus at the periphery of the screen (14), a compromise is made with emphasis on uniformity of focus at the center and the periphery of the screen (14) at the expense of the focus at the center of the screen (14). It has to do a basic design.

Further, the auxiliary coil disclosed in Japanese Utility Model Publication No. 57-45748 uses the current synchronized with the deflection current flowing through the vertical deflection coil, so that the following problem occurs. That is, when the electron beam is deflected in the vertical axis direction, the magnetic field generated in the horizontal direction on the horizontal axis causes the electron beam to be excessively deflected in the vertical axis direction on the electron gun assembly side of the deflecting device, resulting in a funnel neck. Collisions with the inner wall are likely to occur, and a portion of the screen, which is called a neck shadow, where the electron beam does not reach (a portion that does not emit light) is formed. Further, since this auxiliary coil has a structure in which a coil is wound around a magnetic material and a current flows through the coil, it becomes expensive as a correction element, and it is difficult to reduce the price. Further, the deflection device is often used with its impedance changed according to the receiver of each set maker, and the current flowing through the deflection coil differs according to the difference in the impedance. Therefore, it is necessary to change the specifications of the auxiliary coil in accordance with the impedance of the deflection coil in order to make the function of the biasing coil appropriate for such a deflection device, and this is lacking in mass productivity.

In order to solve this problem, Japanese Patent Application No. 1-90221,
As shown in FIG. 18, on the path of the three electron beams between the deflecting device and the electron lens portion of the electron gun assembly, the polarities are oppositely symmetric with respect to the central axis of the deflecting device (121). A pair of pincushion-type deflecting magnetic fields are arranged in the same direction as the arranging direction of the electron beams and in a direction orthogonal to the arranging direction of the three electron beams to compensate for the deflection aberration caused by the deflecting magnetic field formed by the second deflecting coil. And a plurality of permanent magnets (128a), (128b), (128c), and (128d) in which the strengths and arrangement positions of the generated magnetic fields are mutually set.

In this case, the second magnetic field generated by the pincushion magnetic field formed by the permanent magnets (128a) and (128b) arranged in the direction orthogonal to the arrangement direction of the three electron beams exerts on the three electron beams.
A Lorentz force in a direction opposite to the Lorentz force of the barrel-shaped deflection magnetic field of the deflection coil is applied to the three electron beams, and the ellipticalization of the electron beam and the inclination of the pair of side beams caused by the barrel-shaped deflection magnetic field of the second deflection coil are performed. Can be corrected.

Further, the permanent magnets (128c) and (128d) arranged in a direction parallel to the arrangement direction of the three electron beams are adjacent permanent magnets (12c).
8a) and (128b) between the magnetic poles to form a magnetic field that exerts a Lorentz force on the pair of side beams in a direction opposite to the Lorentz force of the barrel-shaped deflection magnetic field of the second deflection coil on the pair of side beams. The inclination of the side beam can be corrected. However, it has become insufficient in recent years for color picture tubes requiring higher convergence characteristics and focus characteristics, such as HDTVs having a 16: 9 aspect ratio and high-definition tubes.

That is, the rod-shaped permanent magnet (128) as described above is
Generally, when magnetized, a deviation occurs between the direction of magnetization and the direction of the central axis of the permanent magnet (128), and the magnetization direction is easily inclined with respect to the central axis of the permanent magnet as shown in FIG. This is because the magnetization of the permanent magnet is generally not performed individually one by one in terms of cost, etc., but as shown in FIG.
9) magnetize together and then individual permanent magnets (128)
It is for producing. And the magnetic field lines (130) for magnetization are not completely parallel to the magnetic material (129), and especially the magnetic field lines (130) at the periphery of the magnetic material (129) are the central axis of the permanent magnet (128). Leaning against. As a result, even if the permanent magnet (128) is mounted at an accurate position, the magnetic field generated by the permanent magnet (128) does not become axially symmetric with respect to the central axis of the deflecting device (121). A correction effect with high accuracy sufficient for improvement cannot be given.

In addition, the convergence characteristics of the three electron beams also have asymmetry on the screen.

(Problems to be Solved by the Invention) The present invention has been made in order to solve the above problems, and accurately arranges the magnetic poles of a permanent magnet at a predetermined position without adversely affecting the convergence characteristics. ,
An object of the present invention is to obtain a color picture tube having good focus characteristics over the entire screen and a deflection device therefor.

As described above, in the self-convergence type in-line type color picture tube, coma aberration occurs in which the convergence of the center beam and the pair of side beams is shifted at the peripheral portion of the screen. Conventionally, to correct this coma, a magnetic body that couples to the rear leakage magnetic field of the deflecting device is disposed on the electron gun structure, or an auxiliary current that is synchronized with the vertical deflection current is supplied to the deflecting device on the electron gun structure side. Some have coils arranged. However, even with this configuration, the spot of the electron beam on the phosphor screen is still distorted into a horizontally long ellipse with the horizontal axis as the long axis at the horizontal and vertical axis ends of the screen, and particularly at the vertical axis end. In the direction in which the spots of a pair of side beams intersect each other at the same time, the focus characteristics cannot be prevented from deteriorating at the periphery of the screen, and the deterioration of the focus characteristics is a major factor that hinders the performance enhancement of the electron gun assembly. In addition, there is a problem that the improvement of the focus characteristic on the entire screen is hindered. Furthermore, even in the case where a bar-shaped permanent magnet is arranged in the deflecting device, it is difficult to generate an axially symmetric correction magnetic field with respect to the central axis of the deflecting device, and a color that requires more accurate focus characteristics and convergence characteristics is required. Sufficient correction could not be made for the picture tube.

[Configuration of the invention]

(Means for Solving the Problems) An in-line type electron gun structure that emits three electron beams arranged in a line in the same plane and includes a center beam and a pair of side beams, and the three electrons emitted from the electron gun structure A first deflecting coil for forming a pincushion-type deflecting magnetic field for deflecting the beam in the arrangement direction, and a second deflecting coil for forming a barrel-type deflecting magnetic field for deflecting the three electron beams in a direction orthogonal to the arrangement direction And a deflecting device having a deflecting device comprising: a deflecting device having a deflecting device and a deflecting device, wherein the deflecting device and the electron lens portion of the electron gun assembly are surrounded by three electron beams on a path and axially symmetrical with respect to the central axis of the deflecting device The vertical axis (Y-axis) and the water are generated so as to generate a pincushion-type magnetic field for compensating for the deflection aberration caused by the deflection magnetic field formed by the second deflection coil. Flat axis (X
), The magnetic pole interval sandwiching the vertical axis is smaller than the interval in the direction of arrangement of the pair of side beams, and the four magnetic poles sandwiching the vertical axis and the horizontal axis sandwiching the horizontal axis 4. The four magnetic poles have the same strength, and the four magnetic poles sandwich the vertical axis.
An annular permanent magnet arrangement with eight magnetic poles arranged to be stronger than one magnetic pole was provided.

(Operation) As described above, when a ring-shaped permanent magnet device composed of eight magnetic poles is arranged around the three electron beam paths between the deflection device and the electron lens unit of the electron gun assembly, the position of the magnetic pole is determined by the deflection device. It can be installed accurately with respect to this, and can generate an axially symmetric magnetic field. Therefore, the ellipticity of the electron beam and the inclination of the pair of side beams caused by the barrel magnetic field of the second deflection coil can be effectively corrected without adversely affecting the convergence characteristics of the three electron beams.

Hereinafter, the present invention will be described based on embodiments with reference to the drawings.

FIG. 1 shows an embodiment of a self-convergence type in-line color picture tube. This color picture tube comprises an envelope (3) comprising a panel (1) and a funnel (2).
The panel (1) faces the shadow mask (4) having a large number of electron beam passage holes formed therein, and emits blue, green, and red light on the inner surface of the panel (1). A phosphor screen (5) comprising a color phosphor layer is formed. Also, three electron beams (B) arranged in a line in the neck (6) of the funnel (2) and passing in the same horizontal plane,
An in-line type electron gun structure (20) for emitting (G) and (R), which will be described later, is provided. Further, the three electron beams (B), (G), and (R) emitted from the electron gun assembly (20) are placed outside the boundary between the cone (8) and the neck (6) of the funnel (2). Deflector (21) for scanning the phosphor screen (5) by deflecting horizontally and vertically
Is installed.

The deflecting device (21) is of a self-convergence type in which three electron beams (B), (G), and (R) are concentrated on a phosphor screen (5) by an asymmetric magnetic field,
For example, a pair of horizontal deflection coils (23) wound in a saddle shape and mounted vertically (Y-axis direction) inside a separator (22) and a core (2) as shown in FIG.
And a pair of vertical deflection coils (25) wound around 4) and mounted outside the separator (22). A pair of horizontal deflection coils (23) of the deflection device (21) generate a mainly pincushion-type deflection magnetic field that deflects the three electron beams emitted from the electron gun assembly (20) in the horizontal direction (X-axis direction). The pair of vertical deflection coils (25) forms a barrel-type deflection magnetic field that deflects the three electron beams in a vertical direction (Y-axis direction) orthogonal to the arrangement direction. In addition,
As used herein, the pincushion-type deflection magnetic field and the barrel-type deflection magnetic field mean that they are collectively a pincushion-type deflection magnetic field and a barrel-type deflection magnetic field, respectively. Further, in the color picture tube of this example, as shown in FIG. 2, the center axis (Z) of the deflecting device (21) is attached to the end (27) of the deflecting device (21) on the side of the electron gun assembly.
An annular permanent magnet device (28) having eight magnetic poles is mounted axially symmetrically with respect to the axis (which generally coincides with the axis of the tube when mounted on a color picture tube). In this permanent magnet device (28), as shown in FIGS. 3 (a) and 3 (b), eight magnetic poles are alternately arranged, and the interval between the magnetic poles sandwiching the X-axis and the Y-axis is not sandwiched. It is smaller than the distance between the magnetic poles. The strengths of the four magnetic poles sandwiching the X axis and the strengths of the four magnetic poles sandwiching the Y axis are equal, and the strengths of the four magnetic poles sandwiching the X axis are the same. It is getting weaker. As for the polarity of the magnetic poles, the magnetic poles in the first quadrant (upper right portion) closest to the Y axis as the N pole when viewed from the screen side are alternately clockwise reversed clockwise.

20mm inside diameter, 23m outside diameter as an example of a permanent magnet device (28)
m, width 5mm magnetic pole interval, magnetic pole gap La = 6mm sandwiching the Y axis,
There is a magnetic pole gap Lb = 5 mm sandwiching the X-axis, and a magnetic pole gap Lc = 26.5 mm between adjacent magnetic poles without sandwiching the axis. At this time,
The surface magnetic flux density of the magnetic pole sandwiching the X axis is 1300 Gauss / cm ² , Y
The surface magnetic flux density of the magnetic pole sandwiching the axis is 1500 Gauss / cm ² .

The electron gun structure (20) of the color picture tube in this example is
As shown in FIG. 4, three independent cathodes (30) arranged in a row in the horizontal direction and first and second grids (31) and (32) for controlling electron emission from the cathode (30). Consisting of an electron beam forming section and third to sixth grids (33) to (36) for accelerating and focusing the three electron beams (B), (G), and (R) emitted from the electron beam forming section. And a convergence cup (37) attached to the sixth grid (36). Incidentally, (38) is a heater for heating the cathode (30). The first, second, and fourth grids (31), (32),
(34) is an integrated plate having three electron beam passage holes corresponding to the three cathodes (30), and the third, fifth, and sixth grids (33), (35) , (36) is also 3
It is composed of a cylindrical electrode having an integral structure in which a plurality of electron beam passage holes are formed.

The interval between the side beam passage holes, that is, the interval Sg in the arrangement direction of the pair of side beams passing through the main lens portion is about 6.6 with respect to the interval between the S pole and the N pole (La = 6 mm) of the permanent magnet.
mm. Furthermore, convergence cup (37)
Around the side beam passage hole at the bottom of the device, there is provided a magnetic field control element composed of magnetic bodies (41a) and (41b) coupled to the rear leakage magnetic field of the deflection device for correcting coma aberration.

When the annular permanent magnet device (28) is disposed around the electron gun structure side end (27) of the deflecting device (21) as described above, the following operation and effects are obtained.

As shown in FIG. 5, the magnetic fields generated by the four magnetic poles sandwiching the Y axis correspond to the barrel-type vertical deflection magnetic field (50) of the vertical deflection coil (25), and have a strong pincushion-type magnetic field (51).
(52), and exerts a Lorentz force that distorts the spot of the electron beam into an elliptical shape whose major axis is in the vertical direction, contrary to the Lorentz force received from the barrel-type vertical deflection magnetic field (50). And correcting a phenomenon in which the beam spots of the paired side beams are inclined and the horizontal axis of the beam spot is a long axis.

On the other hand, the magnetic field generated by the four magnetic poles sandwiching the X axis similarly forms pincushion-type magnetic fields (53) and (54) in the same direction as the pincushion-type horizontal deflection magnetic field. At the same time, as shown in FIG. 6, a magnetic field (55) is applied between the magnetic poles not sandwiching the X axis and the Y axis.
Is formed. The magnetic field (55) applies a pair of side beams (B) and (R) to the pair of side beams based on the barrel-type vertical deflection magnetic field by applying a Lorentz force opposite to the direction in which the spot is inclined by the barrel-type vertical deflection magnetic field. (B),
The inclination of the spot (R) is more effectively corrected.

The magnetic field (55) for the side beams (B) and (R)
In order to make the operation of the first embodiment effective, it is preferable that the interval La between the magnetic poles sandwiching the Y axis is smaller than the interval Sg in the arrangement direction of the pair of side beams.

The effect of correcting the beam spot by the permanent magnet device (28) is, as disclosed in Japanese Utility Model Publication No. 57-45748, the current synchronized with the deflection current flowing through the vertical deflection coil on the electron gun assembly side of the deflection device. As compared with the case where an auxiliary coil for flowing current is added, the correction means is simpler and smaller, can be configured at low cost, and has high mass productivity.

In the case of the auxiliary coil, the magnetic field changes due to the deflection current flowing through the vertical deflection coil. Therefore, if the auxiliary coil attempts to properly correct the beam spot shape near the vertical axis end of the screen, the magnetic field is generated in the middle part of the vertical axis. Becomes too weak, and the beam spot shape cannot be sufficiently corrected. Conversely, to properly correct the beam spot shape in the middle part of the vertical axis, a considerably strong magnetic field is required. In this case, due to the strong magnetic field, the beam spot shape near the vertical axis end is overcorrected and deteriorated, and also adversely affects convergence characteristics and the like. In other words, it is extremely difficult to properly correct the beam spot on the entire screen with the auxiliary coil. However, since the permanent magnet device (28) generates a magnetic field constantly, the beam spot near the vertical axis end of the screen is optimized. If the correction is made, the beam spot in the intermediate portion can be sufficiently corrected at the same time, and the beam spot shape of the entire screen can be improved.

Further, by individually forming the magnetic poles on the annular permanent magnet device as in the present invention, the positions of the magnetic poles can be accurately set. This is because deviation in the direction of the lines of magnetic force when magnetizing unlike a bar-shaped permanent magnet is unlikely to occur. Therefore, an axially symmetric magnetic field can be easily generated, and good focus characteristics can be obtained without adversely affecting the convergence characteristics.

Next, as another embodiment, as shown in FIG. 7, a four-pole magnetic field is formed on each of two annular magnetic members (61a) and (61b), and these are combined to form a permanent magnet device (62). can do. As still another embodiment, as shown in FIG. 8 or FIG. 9, the magnetic members (71a), (71a)
b), (81a) and (81b), each magnetic member (71a),
In (71b), (81a) and (81b), the magnetic poles are magnetized so that the positions of the magnetic poles are separated from each other, and these can be combined to form annular permanent magnet devices (72) and (82). By doing so, each of the magnetic members (71a), (71b), (81a), (81
The magnetization in b) is easy to perform because the distance between the magnetic poles is wide. Further, a permanent magnet device can be made by forming magnetic poles on three or more magnetic members and combining them.

As shown in Fig. 10, the permanent magnet device (28) is turned into a deflection device (21).
May be arranged between the electron gun side end (27) and the core (24). In this case, it is more convenient to divide the permanent magnet device (28) into upper and lower parts as shown in FIG. This division may be not only vertical division but also horizontal division and division in other directions. The division in FIG. 11 may be combined with the method shown in FIGS. 7, 8, and 9.

FIG. 12 shows an electron gun assembly (20) having three independent cathodes (30) arranged in a row in the horizontal direction and first and second grids (31), which control electron emission from the cathodes (30). (32)
A bipotential type comprising an electron beam forming section made up of: and an electron lens section made up of third and fourth grids (33) and (34) for accelerating and focusing three electron beams emitted through the electron beam forming section. A magnetic field composed of magnetic bodies (41a) and (41b) around a side beam passage hole at the bottom of a convergence cup (37) attached to a fourth grid (34) constituting an electron lens part of an electron gun structure In addition to providing a control element, this convergence cup (37)
A permanent magnet device (28) that forms an octupole magnetic field that is axially symmetric with respect to the central axis (55) of the electron gun structure (20) is disposed on the inner side surface of the electron gun assembly (20).

As described above, the permanent magnet device only needs to be in the electron beam passage area on the electron gun assembly side with respect to the deflection device and on the deflection device side with respect to the electron lens portion of the electron gun. Further, the permanent magnet device does not need to be entirely magnetic. It is sufficient that at least the portion forming the magnetic pole can be magnetized. Further, it is needless to say that this magnetization is performed before attaching to the deflection device and the color picture tube.

〔The invention's effect〕

An electron gun assembly side end of a deflecting device or a main lens unit of the electron gun assembly which forms a deflecting magnetic field for deflecting the three electron beams arranged in a line in the same plane on the same plane in the arrangement direction and the direction orthogonal to the arrangement direction. When an annular permanent magnet device that forms an octupole magnetic field is arranged near the electrode located on the phosphor side, the deflection aberration that the magnetic field of the deflecting device exerts on the electron beam by the octupole magnetic field is corrected, and the focus at the periphery of the screen is adjusted. The characteristics can be improved.

[Brief description of the drawings]

1 to 12 are explanatory views of an embodiment of the present invention.
FIG. 1 is a configuration diagram of a self-convergence type in-line color picture tube according to a first embodiment of the present invention, and FIG. 2 is a perspective view showing an arrangement of a pair of upper and lower annular permanent magnet devices at an end of an electron gun assembly of the deflection device. 3 (a) and (b)
Are front and side views showing the shape of the permanent magnet device,
FIGS. 4 (a) and 4 (b) are views showing the configuration of the electron gun structure of the color picture tube and the layout of the magnetic field control elements thereof, and FIG. 5 is a pincushion type formed by the annular permanent magnet device. FIG. 6 is a diagram for explaining the effect of the magnetic field on the spot of the electron beam. FIG. 6 is a diagram for explaining the effect of another magnetic field formed by the annular permanent magnet device on the spot of the electron beam. ), (B), (c), FIGS. 8 (a), (b), (c), FIGS. 9 (a), (b),
FIG. 10 (c) is a side view of another embodiment of an annular permanent magnet device composed of two parts and a combination thereof, and FIG. 10 is an arrangement of another embodiment of an annular permanent magnet in a deflection device. , FIG. 11 is a diagram showing an annular permanent magnet device used in FIG. 10, and FIGS. 12 (a) and (b) are cross-sectional views showing the configuration of an electron gun assembly in which the annular permanent magnet device is arranged. FIG. 13 is a diagram showing the arrangement of a permanent magnet device and a magnetic field control element, FIG. 13 is a configuration diagram of a conventional self-convergence type in-line color picture tube, and FIG. 14 is a configuration of a deflection device attached to the color picture tube. FIG. 15 is an explanatory diagram of a spot shape of an electron beam deflected by a uniform magnetic field of a deflecting device, FIG. 16 is an explanatory diagram of a spot shape of an electron beam deflected by a non-uniform magnetic field of a deflecting device, 17 (a) and (b) FIG. 18 is a view for explaining the action of a pincushion type horizontal deflection magnetic field and a barrel type vertical deflection magnetic field on an electron beam, and FIG. 18 shows a conventional electron beam spot shape in which a pair of upper, lower, left and right permanent magnets are arranged. FIG. 19 is a perspective view showing a deflecting device, FIG. 19 is a diagram showing the direction of magnetization of the permanent magnet in FIG. 18, and FIG. 20 is a diagram showing magnetic lines of force when the permanent magnet is magnetized. 5: Fluorescent screen, 20: Electron gun assembly 21: Deflection device, 23: Horizontal deflection coil 24: Core, 25: Vertical deflection coil 27: End portion of the deflection device on the electron gun assembly 28 ... Annular permanent magnet device 31 First grid 32 Second grid 33 Third grid 34 Fourth grid 35 Fifth grid 35 Sixth grid 37 Convergence cup 39a, 39b: Center beam passage holes 40a to 40d: Side beam passage holes 41a, 41b: Magnetic body 50: Barrel type vertical deflection magnetic field 51, 52, 53, 54: Pincushion magnetic field formed by an annular permanent magnet device 55: Magnetic field formed by magnetic poles sandwiching the X and Y axes of the annular permanent magnet device 61a, 61b 71a, 71b, 81a, 81b: Part of the annular permanent magnet device 62 72, 82 …… 64a, 64b: Part of annular permanent magnet device B, R: A pair of side beams G: Center beam

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-2-78138 (JP, A) JP-A-49-917720 (JP, A) Actually open 50-97332 (JP, U) (58) Field (Int.Cl. ⁷ , DB name) H01J 29/51 H01J 29/76

Claims (6)

(57) [Claims] An electron beam forming portion for forming a three electron beam composed of a center beam and a pair of side beams, and an electron lens portion for converging the three electron beams. An in-line type electron gun assembly for emitting, a first deflection coil for forming a pincushion-type deflection magnetic field for deflecting the three electron beams mainly in the arrangement direction, and a barrel for deflecting the three electron beams in a direction orthogonal to the arrangement direction A deflecting device having a second deflecting coil for forming a shaped deflecting magnetic field, and the three electron beams between the deflecting device and an electron lens portion of the electron gun assembly corresponding to the deflecting magnetic field formed by the second deflecting coil. Around the path of the deflecting device, is axially symmetric with respect to the central axis of the deflecting device, and compensates for the deflection aberration caused by the deflecting magnetic field formed by the second deflecting coil. Eight pole vertical axis so as to generate a pincushion magnetic field (Y-axis) and horizontal axis (X axis)
Is smaller than the gap between the poles
The interval between the magnetic poles sandwiching the vertical axis is smaller than the interval in the arrangement direction of the pair of side beams, and the strengths of the four magnetic poles sandwiching the vertical axis and the four magnetic poles sandwiching the horizontal axis are equal, and the four magnetic poles sandwiching the vertical axis are equal. Magnetic pole sandwiches horizontal axis 4
A color picture tube comprising an annular permanent magnet arrangement arranged to be stronger than the strength of the two magnetic poles. 2. A color picture tube according to claim 1, wherein an annular permanent magnet device is formed from a plurality of members. 3. The magnetic pole of the ring-shaped permanent magnet device has a magnetic pole in the first quadrant (upper right portion) closest to the vertical axis as viewed from the screen side, and has an N pole, and the polarity of the magnetic pole is alternately inverted clockwise. 2. A color picture tube according to claim 1, wherein: 4. An electron gun according to claim 3, wherein said electron gun is an electron gun.
A first deflection coil mounted on a color picture tube for reproducing an image by deflecting and scanning an electron beam on a phosphor screen and deflecting the three electron beams in a direction in which the three electron beams are arranged; A second deflection coil that forms a barrel-shaped deflection magnetic field that deflects the electron beams in a direction perpendicular to the direction in which the electron beams are arranged, wherein the electron gun assembly corresponds to the deflection magnetic field formed by the second deflection coil. In order to generate eight pincushion-shaped magnetic fields around the path of the three electron beams on the side, which are axially symmetric with respect to the center axis of the deflection device and compensate for the deflection aberration caused by the deflection magnetic field formed by the second deflection coil. The magnetic pole interval where the magnetic poles sandwich the vertical axis (Y axis) and the horizontal axis (X axis)
The distance between the magnetic poles that are not pinched, the distance between the magnetic poles sandwiching the vertical axis is smaller than the distance in the arrangement direction of the pair of side beams, and the strengths of the four magnetic poles that sandwich the vertical axis and the four magnetic poles that sandwich the horizontal axis are respectively A deflecting device, characterized in that it has an annular permanent magnet arrangement arranged such that the four poles sandwiching the vertical axis are equally stronger than the four poles sandwiching the horizontal axis. 5. A color picture tube according to claim 4, wherein an annular permanent magnet device is formed from a plurality of members. 6. The magnetic pole of the ring-shaped permanent magnet device has a magnetic pole in the first quadrant (upper right portion) closest to the vertical axis as viewed from the screen side, as an N pole, and the polarity of the magnetic pole is alternately inverted clockwise. 5. A color picture tube according to claim 4, wherein: