JP2001238225A - Display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display device employing a cathode ray tube that can sufficiently suppress color smear and realize remarkably high image quality. SOLUTION: The display device comprises a cathode ray tube having a color selection electrode 20 that is fixed to a frame 21 with a tension provided thereto and having an internal magnetic shield 12 that magnetically shields an electron beam, and of a degaussing coil 16 placed to a funnel 14 of the cathode ray tube. The degaussing coil 16 consists of a couple of 1st and 2nd degaussing coils 16a, 16b placed vertically, and the 1st and 2nd degaussing coils have parallel pars 16a-1, 16b-1 extended nearly in parallel with upper and lower sides of the color selection electrode and have roundabout parts 16a-2, 3, 16b-2, 3 going around from both ends of the parallel parts toward an inner side face of ridges of the funnel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a cathode ray tube (hereinafter, referred to as a cathode ray tube).
And a display device such as a television having a CRT.

[0002]

2. Description of the Related Art Generally, in a CRT, an electron beam emitted from an electron beam emitting means such as an electron gun passes through a hole for passing an electron beam of a color selection electrode and hits a phosphor at a landing point. Emit red, green, or blue light.

Hereinafter, with reference to FIGS. 12 to 15,
A display device including a conventional CRT, for example, a color television will be described. Each figure shows only those structures that are deeply related to changes in the trajectory of the electron beam due to the external magnetic field of the color television. In FIG. 12, a conventional color television is
Between a display panel 10 having a phosphor screen and an electron gun 13 for emitting an electron beam toward the display panel 10, for example.
There is a color selection electrode assembly comprising a color selection electrode 20 and a frame 21, and an external magnetic field shield assembly 18 comprising the color selection electrode assembly and an internal magnetic shield 12 for magnetically shielding an electron beam from an external magnetic field. The display panel 10 includes a funnel 14 joined to the display panel 10 so as to cover the external magnetic field shield structure 18, a neck 19, an explosion-proof band 15, and a degaussing coil 16 disposed on the funnel 14.

FIG. 13 is a side view of the conventional display device shown in FIG. 12, in order to clarify the positional relationship with the degaussing coil 16, a color selection electrode 20 housed inside a CRT.
FIG. 4 is an explanatory side view showing a positional relationship between a degaussing coil 16 and an external magnetic field shield structure 18 in which the projected positions of an angle 21a and upper and lower internal magnetic shields 12 are shown in the side view.

[0005] As shown in FIG. 14, a typical example of a color selection electrode structure including a color selection electrode 20 and a frame 21 is a shadow mask structure 11 a. The shadow mask structure 11a is one in which a color selection electrode 20 having a large number of pores formed therein is curved into a predetermined shape by pressing and fixed to a frame 21 by welding. When trying to make the screen of the CRT flat, this shadow mask 1
Although it is necessary to make the surface 1a closer to flat, the amount of deformation of the shadow mask 11a due to thermal expansion caused by the temperature rise due to the collision of the electron beam increases as the shadow mask 11a becomes closer to flat, and the positional relationship with the phosphor is reduced. It may deviate and impair its function.

As a solution to this, as shown in FIG.
As a color selection electrode structure, a method of using a so-called tension mask structure 11b in which a tension P is applied to a frame 21 in a state where tension P is applied only in the vertical direction of the screen of the color selection electrode 20 having a large number of pores has been proposed. . According to this method, the tension mask structure 1 in a state where tension is applied
1b absorbs the elongation of thermal expansion caused by the collision of the electron beam and prevents deformation.

However, from the electron gun 13 to the display panel 10
When the electron beam receives an external magnetic field such as terrestrial magnetism before reaching the phosphor screen, its trajectory changes due to the Lorentz force, and the electron beam lands at a point shifted from the landing point when there is no external magnetic field. A part or all of the beam spot hits a phosphor different from when there is no color shift, causing a so-called color shift.

In order to suppress this color shift, an internal magnetic shield 12 is provided, and an external magnetic field shield structure 18 is constituted by the internal magnetic shield 12 and a color selection electrode assembly. The external magnetic field shield structure 18 is magnetically shielded to suppress a change in the trajectory of an electron beam due to an external magnetic field. Thus, color misregistration is suppressed.

The external magnetic field shield structure is shown in FIGS.
The angle 21a made of, for example, 36% Ni-Fe material is used as the first frame of the conventional color selection electrode structure shown in FIG.
And a tension mask structure 11b composed of, for example, an arm 21b made of, for example, 42% Ni-Fe material and a color selection electrode 20 made of, for example, 36% Ni-Fe material, and an interior made of, for example, Fe material It is composed of a magnetic shield 12.

Further, a degauss operation is performed to improve the magnetic shielding effect. The degauss operation means that when the external magnetic field shield structure 18 including the color selection electrode structure such as the tension mask structure 11b is considered as a magnetic circuit, the external magnetic field shield structure 18 is subjected to an attenuated alternating magnetic field in the presence of a bias magnetic field, that is, geomagnetism. Is applied by passing an attenuated alternating current through the first degaussing coil 16a and the second degaussing coil 16b.

A substantially quadrangular first degaussing coil 16a of the degaussing coil passes over the color selection electrode 20, passes through a corner above the color selection electrode 20, and wraps the electron gun 13 along the funnel 14. Through the lower side near the neck, along the funnel 14 on the opposite side surface, through the upper corner of the color selection electrode 20, and to the upper side of the color selection electrode 20. Further, the second degaussing coil 16 having a substantially quadrangular shape is used.
b passes under the color selection electrode 20, passes through the lower corner of the color selection electrode 20, and along the ridge of the funnel 14, via the lower side near the neck 19 surrounding the electron gun 13, and on the opposite side Along the ridge line of the funnel 14 on the side surface of the above, the lower part of the color selection electrode 20 is connected to the lower part of the color selection electrode 20 through the lower corner. The first degaussing coil 16a and the second degaussing coil 16b are formed by one connected coil, and are arranged in a vertically asymmetrical figure eight shape.
It is connected to a power supply circuit, and its magnetomotive force is 1000 to
It is about 4000AT.

The ridge line of the funnel 14 in the present invention means a ridge line from a corner of a rectangular display panel to a neck of the funnel. In this case, the ridge line may not be clear because the funnel cross section becomes circular as approaching the neck side, but it is assumed that the ridge line extends from the corner of the rectangular display panel.

In this degauss operation, since the terrestrial magnetism is applied as a bias magnetic field, after the degauss operation, the external magnetic field shield structure 18 including the tension mask structure 11b is more likely to be positioned in the direction of the terrestrial magnetism as the bias magnetic field than in the case where only the terrestrial magnetism is used. Large magnetization is also generated. Due to the magnetization generated in the direction of the terrestrial magnetism, a magnetic field for canceling the terrestrial magnetism is generated inside the external magnetic field shield structure 18. As a result, a magnetic shielding effect is exhibited, a change in the trajectory of the electron beam due to an external magnetic field can be suppressed, and color shift can be suppressed. Therefore, of the magnetic fluxes generated by the degaussing coil 16, by increasing the magnetic flux flowing to the external magnetic field shield structure 18 including the tension mask structure 11b,
It is important to generate enough magnetization to cancel the terrestrial magnetism after the degauss operation in order to reduce the influence of the terrestrial magnetism of the electron beam.

[0014]

However, in the tension mask structure 11b as described above, the color selection electrode 2 is not provided.
Frame 21 which applies tension to the color selection electrode 2
0, and an arm 21b, which is a second frame that supports the angle 21a so as to apply tension to the color selection electrode 20, so that it is structurally oriented in this side direction. There is a part without a geomagnetic shield. Therefore, the horizontal magnetic field component of the terrestrial magnetism, which is the external magnetic field in the side direction of the arm 21b and the tube axis direction of the CRT, is not sufficiently shielded. Further, since the color selection electrode 20 is supported in a state where tension is applied, the magnetic permeability is reduced due to magnetostriction. Further, the magnetic flux generated by the conventional demagnetizing coil 16 arranged in a vertically asymmetrical figure eight shape flows non-uniformly into the tension mask structure 11b having a small magnetic permeability, and the effective tension of the magnetic flux generated by the demagnetizing coil 16 is effectively reduced. A magnetic flux that did not flow to the mask structure 11b was generated.

Therefore, the magnetization generated in the external magnetic field shield structure including the tension mask structure after the degauss operation by the degauss operation by the conventional degaussing coil is shown in FIG.
As shown in FIG. 12A, the demagnetizing coil of the conventional example shown in FIG. 12 is set on a 25-inch CRT, and a numerical analysis of the magnitude of magnetization in the color selection electrode 20 after the degauss operation (second
This will be described in detail in an embodiment. As a result, the magnetization of the color selection electrode 20 is small and not sufficient, so that the horizontal magnetic field component of the terrestrial magnetism is not sufficiently shielded. Therefore, the change of the trajectory of the electron beam due to the horizontal magnetic field component cannot be sufficiently suppressed, and there is a problem that a color shift occurs.

Accordingly, in view of the above problems, the present invention enhances the magnetic shielding effect by sufficiently magnetizing the color selection electrode by degauss operation, and can sufficiently suppress color misregistration as compared with the related art, thereby realizing extremely high image quality. It is an object of the present invention to provide a display device using a cathode ray tube that can be used.

[0017]

The above object can be attained by the following present invention.

That is, the display device of the present invention comprises a cathode ray tube having a color selection electrode fixed to a frame under tension, an internal magnetic shield for magnetically shielding an electron beam, and a funnel of the cathode ray tube. A degaussing coil, wherein the degaussing coil comprises a pair of upper and lower first and second degaussing coils, and the first and second degaussing coils are respectively provided with the color selection electrode. A display device comprising: a parallel portion substantially parallel to an upper side or a lower side; and a wraparound portion extending from both ends of the parallel portion to a side surface inside a ridgeline of the funnel.

Here, at the time of the degauss operation, an external magnetic field shield structure composed of a color selection electrode, a frame, and an internal magnetic shield is considered as a magnetic circuit while the degaussing coil is used as a source of magnetic flux. In this case, as described above, a parallel portion substantially parallel to the upper side or lower side of the color selection electrode in the demagnetizing coil, and a wraparound portion that wraps around both sides of the parallel portion to a side surface inside the ridge line of the funnel, that is, , Not along the ridgeline of the funnel but on the center of the side surface from the ridgeline, the inclination between the linkage surface of the degaussing coil and the internal magnetic shield increases, and the inside of the linkage surface of the degaussing coil increases. Since the cross-sectional area perpendicular to the magnetic shield increases, the magnetic flux flowing parallel to the internal magnetic shield increases. as a result,
Of the magnetic flux generated by the degaussing coil, the magnetic flux flowing through the magnetic circuit increases, and the magnetic flux flowing through the tension mask structure increases, so that the demagnetizing magnetic field is effectively applied to the tension mask structure. For this reason, after the degauss operation performed in the presence of the terrestrial magnetism, which is the bias magnetic field, the external magnetic field shield structure including the tension mask structure generates a larger magnetization in the direction of the terrestrial magnetism, which is the bias magnetic field, than the conventional magnetic field. A magnetic field for canceling geomagnetism is generated inside. As a result, the magnetic shielding effect is increased, the change in the trajectory of the electron beam due to the external magnetic field in the horizontal direction is sufficiently suppressed, and the color shift can be sufficiently suppressed.

Here, the "linkage surface" of the degaussing coil refers to a curved surface of which the magnetic flux component penetrating the curved surface is composed only of a perpendicular component of the curved surface, out of the curved surfaces having the degaussing coil as an outer periphery. The side surface shape of the degaussing coil in the side view explanatory diagram of (a) corresponds to the shape seen from the side where the outer circumference of the interlinking surface overlaps.

In the display device of the present invention, the explosion-proof band provided has a relative magnetic permeability of 2,000 or more and 15,000.
In addition to the above, the first and second degaussing coils each include a portion in which the parallel portion or the wraparound portion includes a portion disposed on the explosion-proof band. Device.

As described above, the explosion-proof band provided has a high magnetic permeability having a relative magnetic permeability of 2,000 or more and 15,000 or less, and an explosion-proof band having a high magnetic permeability is provided at each parallel portion or wraparound portion of the degaussing coil. Since the magnetic circuit including the tension mask structure can further include an explosion-proof band having a high magnetic permeability among the magnetic fluxes generated by the degaussing coil by including the portion disposed above, the magnetic flux flowing through the tension mask structure And the demagnetizing field is effectively applied to the tension mask structure. For this reason, after the degauss operation, a sufficiently large magnetization that cancels the terrestrial magnetism is generated in the tension mask structure, the magnetic shielding effect is increased, and the change in the trajectory of the electron beam due to the external magnetic field in the horizontal direction is sufficiently suppressed. Can be sufficiently suppressed.

Further, in the display device according to the present invention, the first and second degaussing coils may be arranged such that each of the wrap-around portions is a side of the display panel on the left and right side surfaces of the funnel near the color selection electrode. The display device according to claim 1, further comprising a portion extending substantially in parallel with the display device.

As described above, a portion extending substantially parallel to the vertical side of the display panel on the left and right side surfaces of the funnel near the tension mask structure is provided in the wraparound portion of the first and second degaussing coils. The magnetic flux generated by the degaussing coil flows toward the tension mask structure, and the degaussing magnetic field is effectively applied to the tension mask structure. For this reason, after the degauss operation, a sufficiently large magnetization that cancels the terrestrial magnetism is generated in the tension mask structure, the magnetic shielding effect is increased, and the change in the trajectory of the electron beam due to the external magnetic field in the horizontal direction is sufficiently suppressed. Can be sufficiently suppressed.

In the display device according to the present invention, the first and second degaussing coils are arranged such that each of the wraparound portions is on the display panel side across a plane including the color selection electrode surface. The display device is characterized in that the display device includes:

As described above, when the wraparound portions of the first and second degaussing coils include a portion disposed on the display panel side across a plane including the color selection electrode surface, that is, a tension mask structure. The wraparound portion on the nearby funnel side includes a portion disposed closer to the display panel than a parallel portion substantially parallel to the upper or lower side of the tension mask structure, so that the surface of the portion disposed toward the display panel is The magnetic flux generated by the degaussing coil at that portion becomes almost perpendicular to the surface of the color selection electrode and easily flows in parallel along the tension mask structure, and the degaussing magnetic field is effectively applied to the tension mask structure. For this reason, in the degauss operation, a sufficiently large magnetization that cancels the terrestrial magnetism is generated in the tension mask structure, the magnetic shielding effect is increased, and the change in the trajectory of the electron beam due to the external magnetic field in the horizontal direction is sufficiently suppressed, and the color misregistration is performed. Can be sufficiently suppressed.

Further, in the display device according to the present invention, the first degaussing coil and the second degaussing coil each include a wraparound portion including a portion on the side surface of the funnel where the coils are substantially parallel to each other. The display device according to claim 1, wherein

As described above, by providing the portions where the coils are substantially parallel to each other on the side surface of the funnel at the respective wraparound portions of the first degaussing coil and the second degaussing coil,
On the side surface, the leakage of magnetic flux between the upper and lower coils is reduced, and the magnetic flux generated by the degaussing coil effectively flows to the tension mask structure. For this reason, after the degauss operation, a sufficiently large magnetization that cancels the terrestrial magnetism is generated in the tension mask structure, the magnetic shielding effect is increased, and the change in the trajectory of the electron beam due to the external magnetic field in the horizontal direction is sufficiently suppressed. Can be sufficiently suppressed.

The display device according to the present invention is characterized in that the portions where the coils are substantially parallel to each other are left and right side surfaces of the funnel near the color selection electrode.

As described above, by providing portions where the coils are substantially parallel to each other on the left and right side surfaces of the funnel near the tension mask structure, the respective wraparound portions of the first and second degaussing coils are provided. The leakage of the magnetic flux between the upper and lower coils is reduced, and the magnetic flux generated by the degaussing coil effectively flows to the tension mask structure. For this reason, after the degauss operation, a sufficiently large magnetization that cancels the terrestrial magnetism is generated in the tension mask structure, the magnetic shielding effect is increased, and the change in the trajectory of the electron beam due to the external magnetic field in the horizontal direction is sufficiently suppressed. Can be sufficiently suppressed.

The display device of the present invention is characterized in that the first degaussing coil and the second degaussing coil are vertically symmetrically arranged.

By arranging the first demagnetizing coil and the second demagnetizing coil vertically symmetrically in this manner, the magnetic flux generated by the demagnetizing coil is uniformly applied to the tension mask structure without waste. For this reason, after the degauss operation, a sufficiently large magnetization that cancels the terrestrial magnetism is generated in the tension mask structure, the magnetic shielding effect is increased, and the change in the trajectory of the electron beam due to the external magnetic field in the horizontal direction is sufficiently suppressed. Can be sufficiently suppressed.

Further, the display device of the present invention is the display device, wherein the first degaussing coil and the second degaussing coil are formed of one coil.

As described above, by forming the first demagnetizing coil and the second demagnetizing coil from one coil, the workability of mounting the demagnetizing coil is improved, and the magnetic flux generated by the demagnetizing coil is effectively tensioned. Applied to the mask structure. For this reason, after the degauss operation, a sufficiently large magnetization that cancels the terrestrial magnetism is generated in the tension mask structure, the magnetic shielding effect is increased, and the change in the trajectory of the electron beam due to the external magnetic field in the horizontal direction is sufficiently suppressed. Can be sufficiently suppressed. In addition, by forming the degaussing coil from one coil, it is possible to easily apply the attenuated alternating magnetic field synchronized with each degaussing coil during the degauss operation.

[0035]

DESCRIPTION OF THE PREFERRED EMBODIMENTS First Embodiment A first embodiment of the present invention will be described with reference to FIGS. In each of the drawings, only a structure closely related to a change in the trajectory of an electron beam due to an external magnetic field of a color television as an embodiment is shown. The display device is a color television having a CRT.

As shown in FIG. 1, the color television according to the first embodiment has a display panel 10 having a phosphor screen and an electron beam emitted toward the display panel 10, for example, an electron gun 1.
3, an external magnetic field shield structure 18 comprising a tension mask structure 11b, which is a color selection electrode structure, and an internal magnetic shield 12, and is bonded to the display panel 10 so as to cover the electron gun 13 and the external magnetic field shield structure 18. A funnel 14, a neck 19, and first and second degaussing coils 16 a and 16 b disposed above and below the funnel 14.

The tension mask structure 11b is composed of a color selection electrode 20 and a frame 21 that supports the edge of the color selection electrode 20 under tension.
1 is a first frame 21a supporting the color selection electrode 20
And a second frame 21b supporting the first frame 21a
It is composed of

In order to make the screen of the CRT flat, the color selection electrode 20 is supported with a tension of about 80 to 160 kg applied thereto so that the color selection electrode 20 is made almost flat. The expansion of the thermal expansion is absorbed and the deformation of the color selection electrode 20 is prevented. However, the relative permeability, which was about 500 before the tension was applied, has dropped to about 200 due to the application of the tension, and the magnetic flux is less likely to flow than when supported without tension. Is in a state where it is hard to be magnetized sufficiently to cancel.

The external magnetic field shield structure has, for example, a thickness of 1.
An angle 21a as a first frame made of a 4% 36% Ni-Fe material and, for example, a 1.4% thick 42% N
Arm 21b as a second frame made of i-Fe material
And a color selection electrode structure that is a tension mask structure 11b including a color selection electrode 20 made of 36% Ni—Fe material having a thickness of 0.1 mm, for example, and a thickness of 0.15.
mm of an internal magnetic shield 12 made of an Fe material.

FIG. 2A is a side view of the display device according to the first embodiment shown in FIG. 1, in order to clarify the positional relationship with the degaussing coil 16, a color selection electrode housed inside the CRT. FIG. 4 is a side view showing the positional relationship between a degaussing coil 16 and an external magnetic field shield structure 18 showing the projection positions of 20, an angle 21a, and upper and lower internal magnetic shields 12 in the side view. FIG. 2B is a rear view showing the disposition state of the degaussing coil.

As shown in FIGS. 1, 2A and 2B, the degaussing coil is a first degaussing coil 1 formed in a saddle shape.
6a is a second frame 21b that passes from one end of the parallel portion 16a-1 extending in parallel along the upper side of the color selection electrode 20 through the upper corner of the color selection electrode 20, and is inside the ridge line of the funnel 14. The neck 19 that wraps the electron gun 13 from the wraparound portion 16a-2 wrapping around the side direction of the
From the wraparound portion 16 a-3 wrapping in the side direction of the second frame 21 b inside the ridgeline of the funnel 14 on the opposite side via the near upper side, passing through the upper corner of the color selection electrode 20. To the parallel portion 16a-1 extending in parallel along the upper side of the color selection electrode 20. First degaussing coil 16a and second degaussing coil 16
b is an upper part or a lower part of the color selection electrode 20 symmetrically in the vertical direction, for example, in the vicinity of the color selection electrode 20, for example, the color selection electrode 20.
3 mm neck side, and the magnetomotive force is 2 mm.
It is 300AT.

The shape of the degaussing coil is the first and the second.
The degaussing coil may be provided with a parallel portion extending substantially in parallel along the upper side or lower side of the color selection electrode and a wraparound portion wrapping around a side surface inside the ridge line of the funnel. For example, in addition to the saddle shape, a boat shape and other shapes can be adopted. In this case, it is desirable that the parallel portion includes a straight line portion.

In the present invention, the vicinity of the color selection electrode 20 means that the magnetic flux generated from the degaussing coil 16 is the same as that of the color selection electrode 2.
This means that the distance between the degaussing coil 16 and the color selection electrode 20 in the tube axis direction is shorter than the distance between the color selection electrode 20 and the end of the frame 21 in the tube axis direction so that a large amount flows to zero.

The electron beam emitted from the electron gun 13 is
It passes through the electron beam passing pores of the color selection electrode 20 and hits the phosphor of the display panel 10 at the landing point.
Emit red, green, or blue light.

Between the electron gun 13 and the fluorescent screen of the display panel 10, on the left and right side surfaces of the funnel, the first and second degaussing coils 16a and 16b have a wraparound portion 16a wrapping around the side surface inside the ridgeline of the funnel. -2, 3,
By providing 16b-2 and 16b, the inclination between the linkage surface of the degaussing coil and the internal magnetic shield 12 increases, and the cross-sectional area of the linkage surface of the degaussing coil perpendicular to the internal magnetic shield 12 increases, so that the internal magnetic field increases. The magnetic flux 30 flowing in parallel along the shield 12 increases. As a result, the magnetic flux generated in each degaussing coil 16 in the degauss operation efficiently flows to the external magnetic field shield structure 18 constituted by the tension mask structure 11b and the internal magnetic shield 12. For this reason, after the degauss operation, a sufficiently large magnetization for canceling the terrestrial magnetism is generated in the tension mask structure 11b, the magnetic shielding effect is increased, and the change in the trajectory of the electron beam due to the external magnetic field in the horizontal direction is sufficiently suppressed. The displacement can be sufficiently suppressed, and high image quality can be realized.

Second Embodiment A second embodiment of the present invention will be described with reference to FIGS. Only the structures that are deeply related to the change in the trajectory of the electron beam due to the external magnetic field of the color television as the embodiment are shown. As shown in FIGS. 3 and 4, the display device of the second embodiment has an explosion-proof band 15 ′ having a high magnetic permeability.
0 and a part of the first degaussing coil 16a and a part of the second degaussing coil 16b are respectively disposed on a high magnetic permeability explosion-proof band 15 ', as shown in FIGS. 1 and 2. Different from the first embodiment. The high magnetic permeability in the present invention means that the relative magnetic permeability is 1.3 to 1 times that of the conventional explosion-proof band.
It is 2000 to 15000, which is 0 times.

The explosion-proof band having a high magnetic permeability has a width of 5% to 20% of the diagonal dimension of the display panel and is disposed so as to surround the color selection electrode. The diagonal dimension is 635mm for 25 inch CRT
The explosion-proof band has a width of 55 mm and a thickness of 1.0, for example.
mm and a relative permeability of about 3000, and the panel side end is disposed 30 mm from the color selection electrode 20 and the neck side end is disposed 25 mm from the color selection electrode 20.

The degaussing coil of the conventional example shown in FIG. 12 and the degaussing coil according to the second embodiment (Example 2) shown in FIG. 3 were set on a 25-inch CRT, respectively. FIG. 5 shows the results of the numerical analysis of the magnitude of the magnetization in FIG. 5, and FIG. 6 shows the results of measuring the amount of electron beam movement under each condition. In the numerical analysis, a non-linear magnetic field analysis is performed by a three-dimensional finite element method in consideration of a hysteresis magnetic characteristic of a magnetic material by a curling model theory, and the analysis region is divided into about 70,000 finite elements. The measurement of the amount of electron beam movement is based on the external vertical magnetic field H
_ver is 35μT constant, external horizontal magnetic field (east-west direction H _ew and tube axis direction H _Tube) is carried out by measuring the amount of color misregistration on the display panel 10 surface when the 30μT and when 0MyuT. Each time a measurement is performed, a degauss operation of applying a decaying alternating magnetic field by each degaussing coil is performed. The measurement point is a corner of the display panel 10.

The upper part of the screen of the display panel is north, and the lower part is
East-west magnetic field H with south, right east, left west _ewThink of this
Outside, tube axis magnetic field H parallel to tube axis direction_tubeHit the north-south direction
Vertical magnetic field H_verShall be considered.

By performing the degauss operation in the presence of the terrestrial magnetism as the bias magnetic field, after the degauss operation, the external magnetic field shield structure 18 including the color selection electrode 20 has a larger magnetization in the direction of the terrestrial magnetism as the bias magnetic field. Then, a magnetic field for canceling geomagnetism is generated inside the external magnetic field shield structure 18. Therefore, it can be said that the greater the magnetization of the color selection electrode 20 after degauss and the more uniform, the more uniform the geomagnetism can be.

The upper and lower first and second degaussing coils 16a, 1
The demagnetizing coil 16 b is provided on the inner side surface of the funnel 14 on the inner side from the ridge line of the funnel 14, and is provided on the explosion-proof band 15 having high magnetic permeability.
The inclination between the intersecting surface of the demagnetizing coil 16 and the internal magnetic shield 12 increases, and the cross-sectional area of the intersecting surface of the degaussing coil 16 perpendicular to the internal magnetic shield 12 increases. Increase. As a result, a large amount of magnetic flux generated from the degaussing coil 16 in the degauss operation flows into the external magnetic field shield structure 18 constituted by the color selection electrode structure and the internal magnetic shield 12. For this reason, as shown in FIG. 5B, after the degauss operation, a sufficiently large magnetization for canceling the terrestrial magnetism is generated in the tension mask structure 11b, and the magnitude of the magnetization of the color selection electrode 20 after the degauss is smaller than that of the conventional example. 5 (a) when the demagnetizing coil is used, the magnetic shielding effect is improved, and as shown in FIG. 6, the change in the trajectory of the electron beam due to the external magnetic field can be suppressed by about 25%. Thereby, color shift is suppressed, and high image quality can be realized.

Third Embodiment A third embodiment of the present invention will be described with reference to FIG. As shown in FIG. 7, the display device according to the third embodiment has the tension mask structure 11b near the wraparound portions 16a-2, 3, 16b-2, 3 of the first degaussing coil 16a and the second degaussing coil 16b. Providing a portion extending substantially parallel to the vertical side of the display panel 10 on the left and right side surfaces of the funnel 14, and providing a portion where the coils are substantially parallel to each other on the left and right side surfaces of the funnel 14.
This is different from the second embodiment shown in FIG.

FIG. 8 shows the results of numerical analysis of the magnitude of magnetization in the color selection electrode 20 after the degauss operation by setting the degaussing coil (Example 3) of the third embodiment shown in FIG. 7 on a 25-inch CRT. Show. Numerical analysis considers the hysteresis magnetic properties of magnetic materials by curling model theory,
A non-linear magnetic field analysis is performed by a three-dimensional finite element method, and the analysis region is divided into about 70,000 finite elements.

First degaussing coil 16a and second degaussing coil 1
6b of each wraparound portion 16a-2, 3, 16b
-2, 3 are provided on the left and right side surfaces of the funnel 14 near the tension mask structure 11b so as to extend substantially parallel to the vertical sides of the display panel 10, and the coils on the left and right side surfaces of the funnel 14 are substantially connected to each other. By providing the portions arranged in parallel, the inclination between the linkage surface of the degaussing coil 16 and the internal magnetic shield 12 increases, and the cross-sectional area of the linkage surface of the degaussing coil 16 perpendicular to the internal magnetic shield 12 increases. Therefore, the magnetic flux 30 flowing in parallel along the internal magnetic shield 12 increases. As a result, the magnetic flux generated by the degaussing coil 16 flows toward the tension mask structure 11b, the leakage of the magnetic flux between the upper and lower coils on the side of the CRT is reduced, and the demagnetizing magnetic field is effectively applied to the tension mask structure 11b. . For this reason, as shown in FIG. 8, after the degauss operation, a sufficiently large magnetization for canceling the terrestrial magnetism is generated in the tension mask structure 11b, the magnetic shielding effect increases, and the trajectory of the electron beam changes due to the horizontal external magnetic field. Can be sufficiently suppressed, color misregistration can be sufficiently suppressed, and high image quality can be realized.

Fourth Embodiment A fourth embodiment of the present invention will be described with reference to FIG. As shown in FIG. 9, the display device of the fourth embodiment differs from the third embodiment shown in FIG. 7 in that the first degaussing coil 16a and the second degaussing coil 16b are formed by one coil.

The demagnetizing coil (Example 4) of the fourth embodiment shown in FIG. 9 was set on a 25-inch CRT, and the result of numerical analysis of the magnitude of the magnetization in the color selection electrode 20 after the degauss operation is shown in FIG. Show. In the numerical analysis, a nonlinear magnetic field analysis is performed by a three-dimensional finite element method in consideration of a hysteresis magnetic characteristic of a magnetic material by a curling model theory, and an analysis region is divided into about 70,000 finite elements.

The left and right side surfaces of the funnel 14 near the tension mask structure 14 are provided on the respective wraparound portions 16a-2, 3, 16b-2, 3 of the first and second degaussing coils 16a and 16b formed of one coil. In addition, a portion extending substantially parallel to the vertical side of the display panel 10 is provided, and a portion that makes the coils substantially parallel to each other is provided on the side surface of the funnel 10 so that the degaussing coil 16 is provided.
The inclination between the intersecting surface of the demagnetizing coil 16 and the internal magnetic shield 12 increases, and the cross-sectional area of the intersecting surface of the degaussing coil 16 perpendicular to the internal magnetic shield 12 increases. Increase. As a result, the magnetic flux generated by the degaussing coil 16 is applied to the tension mask structure 11.
b, and the leakage of magnetic flux between the upper and lower coils on the side of the CRT is reduced. Also, the first degaussing coil 1
The workability of attaching the degaussing coil is improved by forming the degaussing coil 6a and the second degaussing coil 16b by one coil, and the degaussing magnetic field is effectively applied to the tension mask structure 11b. Therefore, as shown in FIG. 10, after the degauss operation, a sufficiently large magnetization for canceling the terrestrial magnetism is generated in the tension mask structure 11b, the magnetic shielding effect becomes large, and the change of the trajectory of the electron beam due to the external magnetic field in the horizontal direction. Can be sufficiently suppressed, color misregistration can be sufficiently suppressed, and high image quality can be realized.

Fifth Embodiment A fifth embodiment of the present invention will be described with reference to FIG.
As shown in FIG. 11, the display device according to the fifth embodiment includes the first device.
And the second demagnetizing coils 16a and 16b are disposed on the display panel 10 side across the plane including the color selection electrode surface 20 in the respective wraparound portions 16a-2, 3, 16b-2 and 3. In other words, the provision of a portion where the degaussing coil 16 is disposed on the left and right side surfaces of the explosion-proof band 15 near the tension mask structure 11b closer to the display panel 10 than the upper side or lower side of the color selection electrode 20 is provided. FIG.
Is different from the second embodiment shown in FIG.

First and second degaussing coils 16a, 16b
To the respective wraparound portions 16a-2, 3, 16b-
2, 3 include a portion disposed on the display panel side across the plane including the color selection electrode surface, that is, the funnel 14 near the tension mask structure 11b.
In the left and right side surfaces of the demagnetizing coil 16, a portion provided on the display panel side rather than a parallel portion parallel to the upper side or lower side of the tension mask structure 11 b is provided in the wraparound portion.
The inclination between the intersecting surface of the demagnetizing coil 16 and the internal magnetic shield 12 increases, and the cross-sectional area of the intersecting surface of the degaussing coil 16 perpendicular to the internal magnetic shield 12 increases. Increase. As a result, the magnetic flux generated by the degaussing coil 16 is applied to the tension mask structure 11.
b, and the demagnetizing magnetic field is effectively applied to the tension mask structure 11b. As a result, the workability of mounting the degaussing coil can be improved, and after the degauss operation, a sufficiently large magnetization for canceling the terrestrial magnetism is generated in the tension mask structure 11b, the magnetic shielding effect increases, and the horizontal external A change in the trajectory of the electron beam due to the magnetic field can be sufficiently suppressed, color shift can be sufficiently suppressed, and high image quality can be realized.

In the above description of the present invention, a case has been described in which the present invention is applied to a tension mask type in which a color selection electrode having a large number of pores is fixed to a frame with tension applied only in the vertical direction of the screen. However, the present invention is not limited to this, and a method in which tension is applied to the color selection electrodes in both the vertical direction and the horizontal direction of the screen in a state where tension is applied, and a large number of strips called aperture grills are formed in the screen vertical direction. The present invention can be applied to all the systems in which the color selection electrodes are fixed to the frame in a state in which tension is applied, such as a system in which the tension is applied to the frame in a state in which the tension is applied, and the same effect is exerted.

In the case where the screen of the color selection electrode is fixed to the frame in a state where tension is applied to the screen in the left-right direction, the degaussing coil may be arranged on either side of the tube axis from the above-described degaussing coil arrangement. In this case, the same effect as the present invention can be obtained.

In the above embodiment, Ni-Fe
Although the case of a tension mask made of a material has been described as an example, the present invention can be applied to a display device using a tension mask made of another magnetic material such as an Fe material.

In the above embodiment, the case of the explosion-proof band made of Fe material has been described as an example.
It can be applied to a display device using an explosion-proof band made of another magnetic material such as a material.

In the above embodiment, the case where the internal magnetic shield is made of Fe is described as an example. However, the present invention can be applied to a display device using an internal magnetic shield made of another magnetic material such as permalloy.

In the above embodiment, a 25-inch color television has been described as an example, but the present invention can be applied to other display devices using an inch-size cathode ray tube.

In the above embodiment, a color television was described as an example. However, the present invention is not limited to this, and can be applied to other display devices using a cathode ray tube, such as a CRT display monitor.

[0067]

According to the display device using the cathode ray tube of the present invention, the parallel portions extending parallel to the first and second demagnetizing coils along the upper side or the lower side of the color selection electrode and the ridge line of the funnel. By providing a wrap around portion on the inner side surface, that is, a portion that goes around the center of the side surface from the ridge line instead of along the ridge line of the funnel, the inclination between the linkage surface of the degaussing coil and the internal magnetic shield is provided. And the cross-sectional area perpendicular to the internal magnetic shield on the interlinking surface of the degaussing coil increases, so that the magnetic flux flowing in parallel along the internal magnetic shield increases. As a result, of the magnetic flux generated by the demagnetizing coil, the magnetic flux flowing through the external magnetic field shield structure including the tension mask structure increases, and the magnetic flux flowing through the tension mask structure increases, so that the demagnetizing magnetic field is effectively applied to the tension mask structure. . Therefore, by performing the degauss operation in the presence of the geomagnetic field that is the bias magnetic field,
After the degauss operation, a larger magnetization is generated in the external magnetic field shield structure including the color selection electrode in the direction of the terrestrial magnetism, which is a bias magnetic field, than in the external magnetic field shield structure, and a magnetic field for canceling the terrestrial magnetism is generated inside the external magnetic field shield structure. As a result, the magnetic shielding effect is increased, the change in the trajectory of the electron beam due to the external magnetic field in the horizontal direction is sufficiently suppressed, the color shift can be sufficiently suppressed, and high image quality can be realized.

[Brief description of the drawings]

FIG. 1 is a perspective view illustrating a configuration of a display device according to a first embodiment.

FIGS. 2A and 2B are explanatory side views showing a positional relationship between a degaussing coil and an external magnetic field shield structure according to the first embodiment, and a rear view showing an arrangement state of the degaussing coil.

FIG. 3 is a perspective view illustrating a configuration of a display device according to a second embodiment.

FIG. 4 is an explanatory side view showing a positional relationship between a degaussing coil and an external magnetic field shield structure according to a second embodiment.

FIG. 5 is a magnetization distribution diagram of a color selection electrode by a numerical analysis after a degauss operation using a degaussing coil (a) of a conventional example and a degaussing coil (b) of a second embodiment.

FIG. 6 is a graph showing the amount of electron beam movement after a degauss operation by the conventional degaussing coil and the degaussing coil of the second embodiment.

FIG. 7 is an explanatory side view showing a positional relationship between a degaussing coil and an external magnetic field shield structure according to a third embodiment.

FIG. 8 is a magnetization distribution diagram of a color selection electrode by numerical analysis after a degauss operation by a degaussing coil according to a third embodiment.

FIGS. 9A and 9B are a side view illustrating a positional relationship between a degaussing coil and an external magnetic field shield structure according to a fourth embodiment, and a rear view illustrating a disposition state of the degaussing coil.

FIG. 10 is a magnetization distribution diagram of a color selection electrode by numerical analysis after a degauss operation by a degaussing coil according to a fourth embodiment.

FIG. 11 is an explanatory side view showing a positional relationship between a degaussing coil and an external magnetic field shield structure according to a fifth embodiment.

FIG. 12 is a perspective view illustrating a configuration of a conventional display device.

FIG. 13 is an explanatory side view showing a positional relationship between a conventional degaussing coil and an external magnetic field shield structure.

FIG. 14 is a perspective view showing a shadow mask structure, which is a conventional CRT color selection electrode structure.

FIG. 15 is a perspective view showing a tension mask structure which is a conventional CRT color selection electrode structure.

[Explanation of symbols]

H _ver Vertical magnetic field _Hew East-west magnetic field H _tube tube axial magnetic field 10 Display panel 11a Shadow mask structure 11b Tension mask structure 12 Internal magnetic shield 13 Electron gun 14 Funnel 15 Explosion-proof band 15 'Explosion-proof band with high permeability 16a First degaussing coil 16a -1 Parallel part 16a-2 Circular part 16a-3 Circular part 16b Second degaussing coil 16b-1 Parallel part 16b-2 Circular part 16b-3 Circular part 17 Electron beam orbit 18 External magnetic field shield structure 19 Neck 20 Color selection electrode 21 Frame 21a Angle 21b Arm 30 Magnetic flux

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Kaneyoshi Takashi Kadoma 1006 Kadoma, Osaka Pref. Matsushita Electric Industrial Co., Ltd. F term (reference) 5C060 CM04 CM10 CN05 JA18

Claims (8)

[Claims] 1. A cathode ray tube having a color selection electrode fixed to a frame under tension and an internal magnetic shield for magnetically shielding an electron beam, and a degaussing coil disposed in a funnel of the cathode ray tube The degaussing coil comprises a pair of upper and lower first and second degaussing coils, and the first and second degaussing coils are respectively arranged along an upper side or a lower side of the color selection electrode. A display device comprising: a parallel portion extending substantially in parallel; and a wraparound portion extending from both ends of the parallel portion to a side surface inside a ridgeline of the funnel. 2. The explosion-proof band provided has a relative magnetic permeability of 2,000 or more and 15,000 or less, and the first and second degaussing coils are respectively provided with the parallel portion or the wraparound portion. Comprises a portion disposed on the explosion-proof band.
The display device according to claim 1. 3. The first and second degaussing coils, wherein each of the wraparound portions extends substantially parallel to a side of the display panel on left and right side surfaces of the funnel near the color selection electrode. The display device according to claim 1, wherein the display device includes a portion. 4. The first and second degaussing coils, wherein each of the wraparound portions includes a portion disposed on the display panel side across a plane including the color selection electrode surface. The display device according to claim 1, wherein: 5. The first degaussing coil and the second degaussing coil, wherein each of the wraparound portions includes a portion on the side surface of the funnel where the coils are substantially parallel to each other. 5. The display device according to any one of items 1 to 4. 6. The display device according to claim 5, wherein the portions where the coils are substantially parallel to each other are left and right side surfaces of the funnel near the color selection electrode. 7. The display device according to claim 1, wherein the first degaussing coil and the second degaussing coil are vertically symmetrically arranged. 8. The display device according to claim 1, wherein the first degaussing coil and the second degaussing coil are formed of one coil.