KR20000066220A - Cathode-ray tube - Google Patents

Abstract

PURPOSE: A CRT is provided to reduce deflection electric power and to enhance deflection sensitivity by optimizing the thickness of a pyramidal yoke installation section. CONSTITUTION: A CRT comprises a panel(3) having fluorescent screen in the inner side, a funnel(4) is connected with the panel(3), and a neck(7) combined to the end of the funnel(4) in the smaller diameter. The neck(7) installs an electron gun opposed to the fluorescent screen. The CRT further has a pyramidal yoke installation section(100) extended from the end of the neck(7) to the panel(3). The outer shape of the yoke installation section has a pin cushion configuration of gradually increasing in respect to the tubular axis in the horizontal and vertical directions. The inside outline of the yoke installation section(100) has a substantially perpendicular shape. The amount of the pin cushion in the horizontal direction is 0.05 to 2.5 millimeter. The amount of the pin cushion in the vertical direction is 0.05 to 2.0 millimeter.

Description

Cathode Ray Tube

The present invention relates to a cathode ray tube such as a color receiving tube, a color monitor, and the like, in particular, a pyramid of the yoke mounting portion of a wide-angle vacuum exterior container, while sufficiently securing internal pressure pressure, reducing deflection power and maximizing deflection sensitivity. It relates to a cathode ray tube to be compatible.

For example, a color cathode ray tube generally includes a vacuum face container comprising a glass face panel having a generally rectangular display portion, a funnel-shaped glass funnel connected in succession to the face panel, and a cylindrical glass neck connected in succession to the funnel. Equipped.

In the neck, an electron gun that emits three electron beams is installed. Also, a deflection yoke is fitted from the outer circumference of the neck to the outer circumference of the funnel.

The funnel has a yoke mount extending from the connection with the neck to the position where the deflection yoke is mounted.

In such a cathode ray tube, the electron gun is of an in-line type that emits three electron beams arranged in a row on the same horizontal plane, and the pincushion and vertical deflection magnetic fields generate a horizontal deflection magnetic field in which the deflection yoke is generated. Barrels are used to deflect three arrayed electron beams emitted from the electron gun by the horizontal and vertical deflection magnetic fields, thereby concentrating three electron beams in a row arrangement throughout the screen without requiring any special correction means. Self-converging inline color cathode ray tubes using non-uniform magnetic fields have been widely used.

In such a color cathode ray tube, the deflection yoke is a large power consumption source, and in the reduction of the power consumption of the cathode ray tube, it is important to reduce the power consumption of the deflection yoke. In other words, in order to increase the screen brightness, the cathode voltage which finally accelerates the electron beam must be increased.

In addition, in order to cope with office automation (OA) devices such as high definition television (HDTV) and personal computer (PC), the deflection frequency must be increased, but this causes an increase in deflection power.

In general, in order to reduce the deflection power or the leakage magnetic field, the neck diameter of the cathode ray tube is reduced, the outer diameter of the yoke mounting portion to which the deflection yoke is mounted is reduced, and the working space of the deflection magnetic field is reduced, so that the deflection magnetic field is effective for the electron beam. It can work.

However, in general, such a cathode ray tube is designed to deflect yoke based on a funnel, but in a pyramidal funnel and a deflection yoke structure, in the design of a funnel cone part, a so-called yoke mounting part, an explosion-proof characteristic and a beam strike neck (BSN: Set the optimum internal shape in consideration of Beam Strike Neck, deflection yoke design → deflection yoke shape modeling → magnetic field calculation → electron trajectory calculation → funnel bulb stress calculation ¡Æ the funnel must be designed based on the deflection yoke (DY), as in the order of redesigning the deflection yoke (DY shape modeling), which results in deflection sensitivity and Optimization of the outer surface design of the funnel to improve the pressure resistance considering the explosion proof was required.

As an example of such a conventional cathode ray tube, a colored cathode ray tube is shown in FIGS. 1 and 2.

The color cathode ray tube includes a vacuum outer container 10 made of glass.

The vacuum outer container 10 includes a panel 3 having a substantially rectangular shaped effective portion 1, a skirt portion 2 provided at the periphery of the effective portion, and a funnel-shaped funnel 4 bonded to the skirt portion 2. ) And a cylindrical neck 7 extending from the funnel.

The effective part 1 of the panel 3 is formed in the substantially rectangular shape which has the horizontal axis X and the vertical axis Y orthogonal to each other through the tube axis Z of a cathode ray tube.

Furthermore, the deflection yoke 6 is mounted on the outside from the neck 7 side to the funnel 4 side, and the funnel 4 is connected from the connection with the neck 7 to the position at which the deflection yoke 6 is mounted. It has a small diameter part and what is called a yoke mounting part 12 extended toward the panel 3 side.

On the inner surface of the effective portion 1 of the panel 3, a three-color phosphor layer having a dot or stripe shape which emits light in blue, green, and red, and the phosphor layer A phosphor screen 5 made of a stripe-shaped light shielding layer formed therebetween is provided.

Also, in the vacuum outer container 10, a shadow mask 11, which is a color screening electrode, is disposed inside the opposing phosphor screen 5 on the inside.

In the neck 7, an electron gun 9 for emitting three electron beams 8 is provided. The three electron beams 8 emitted from the electron gun 9 are deflected by the horizontal and vertical deflection magnetic fields generated by the deflection yoke 6, and the fluorescent screen 5 is horizontally and vertically scanned through the shadow mask 11. The color image is displayed by doing.

The yoke mounting portion 12 of the funnel 4 to which the deflection yoke 6 is mounted in the cathode ray tube is formed in a substantially pyramidal shape. Here, the deflection yoke 6 is a saddle type having a low leakage magnetic field and is a cylindrical synthetic resin frame that fixes the vertical deflection coil, the horizontal deflection coil and the core. Specifically, the pyramidal yoke mounting portion 12 has a circular cross section perpendicular to the tube axis Z in the vicinity of the connecting portion with the neck 7, and is circular in the same shape as the neck 7, but near the center along the tube axis Z direction. In the vicinity of the end portion on the side of the phosphor screen 5, as shown in FIGS. 3 and 4, a substantially rectangular shape is matched to the shape of the effective portion 1 of the panel 3.

As shown in FIG. 4, in the part in which the cross-sectional shape was formed in substantially rectangular shape, the cross-sectional outer side outline of the yoke mounting part 12 is a horizontal axis | shaft (in a horizontal, vertical, diagonal direction of the effective part 1 contained in the panel 3). X), when having a vertical axis (Y), a diagonal axis (D), a pair of arcs 19 of a radius (Rx) centered on the horizontal axis (X) and a radius centered on the vertical axis (Y) ( A pair of arcs 20 of Ry and an arc 21 of radius Rd having a center in the vicinity of the diagonal axis D are formed in a substantially rectangular shape.

In particular, the deflection yoke 6 is mounted such that the short edge on the panel side is located near the inflection point 26, and the yoke mounting portion 12 becomes substantially at least from the connection with the neck 7 to the short edge. In addition, the inflection point 26 of the outer contour of the funnel 4 is formed at the same coordinates in the coordinates in the tube axis Z direction with respect to the long axis X, the short axis Y, and the diagonal axis D.

In other words, in the cross section of the yoke mounting portion 12, the inner surface shape is the inflection point 26 of the major axis (X), the minor axis (Y), the diagonal axis (D) is formed with the same coordinates in the coordinates of the tube axis (Z) direction and the neck ( 7) has an inner diameter La in the major axis direction, an inner diameter Sa in the minor axis direction, and an inner diameter da in the diagonal axis direction from the connection portion 7) to the short edge of the deflection yoke 6.

In Fig. 3, the yoke mounting portion 12 has an outer diameter DA in the direction of the diagonal axis D and an outer diameter in the major axis direction from the connecting portion with the neck 7 to the screen side end of the deflection yoke 6, that is, across the edge. (LA) and the outer diameter SA in the uniaxial direction.

In this way, the yoke mounting portion 12 has a circular shape having a shape substantially the same as that of the neck 7 at the connection portion with the neck 7, but the outer diameter DA in the diagonal axis D direction as it approaches the phosphor screen 5 side. ), The outer diameters LA and SA in the long axis and short axis direction are changed to become smaller gradually, and the shape in the cross section perpendicular to the tube axis Z is almost rectangular.

On the other hand, as shown in FIG. 3, the inner surface shape of the yoke mounting part 12 is not a plane but a pincushion shape which protruded in the tube-axis direction. That is, in the cross section orthogonal to the tube axis Z of the yoke mounting portion 12, the inner contour of the yoke mounting portion is not completely rectangular but is a convex curve in which each side protrudes in the tube axis Z direction.

And the short side 23 of the inner contour of the yoke mounting portion 12 is formed in a convex curve having a top on the horizontal axis (X), each long side 24 is formed in a convex curve having a top on the vertical axis (V) have.

In the case where the long and short sides 24 and 23 of the inner contour are convex curves, the difference is caused by the difference between the inner and outer diameters LA and SA in the major and minor axes. In order to avoid the extreme fall of the thickness of the part vicinity, each part is formed in circular arc-shaped curved surface, ie, circular arc 21, 25 surface on both inner surface and outer surface.

The inner contour shape of the yoke mounting portion 12 and the thickness of the long side and the short side are set in accordance with the shape of the electron beam passing region 22 in the yoke mounting portion 12.

Accordingly, as described above, the inner contour of the cross section of the yoke mounting portion 12 is formed in a convex curve to form a pincushion shape that approximates the electron beam passing region 22, thereby making the inner surface of the yoke mounting portion 12 an electron beam passing region 22. Is connected to as much as possible. For example, the gap between the inner surface of the yoke mounting portion 12 and the electron beam passing region 22 is set to about 1 mm.

The inner contour shape of the cross section of the yoke mounting part 12 mentioned above can be defined as follows. That is, as shown in FIG. 5, in the cross section orthogonal to the tube axis Z of the yoke mounting part 12, the straight line A and the yoke mounting part which form the angle (theta) with respect to the horizontal axis X via the tube axis Z. (12) The intersection of the inner contour is Pi (θ), the shortest distance between Pi (θ) and the horizontal axis (X) is Piv (θ), and the shortest distance between Pi (θ) and the vertical axis (Y) is Pih In the case where (θ) is assumed, the inner contour of the yoke mounting portion 12 has the maximum value or the minimum value dPiv (θ ₀ ) / dθ = 0 at an angle θ ₀ (0 <θ ₀ <90). Expressed as a function of non-forging or non-forging, with Pih (θ) equaling or increasing the non-forging with the maximum value dPih (θ ₀ ) / dθ = 0 at an angle θ ₀ (0 <θ ₀ <90), or It is formed in the shape represented by a non-forging reduction function. In other words, the inner surface of the yoke mounting portion 12 has a shape having a portion that becomes convex in the tube axis Z direction with respect to the vertical axis Y or the horizontal axis X.

As described above, the yoke mounting portion 12 of the funnel 4 is made into a substantially rectangular shape instead of a curved surface when the outer contour of the cross section is based on the diagonal axis, and each side of the inner contour is convex in the tube axis direction. As a result, the inner surface of the yoke mounting portion 12 can be brought into close proximity to the electron beam passing region 22, whereby the deflection efficiency of the deflection yoke 6 is improved and the deflection power can be reduced.

Thus, if the yoke mounting portion 12 to which the deflection yoke is mounted is formed in a pyramidal shape, the diameters of the deflection yoke in the long axis (horizontal axis: X axis) and short axis (vertical axis: Y axis) directions can also be reduced, so that the deflection yoke is horizontal and vertical. The deflection coils can be approached to the electron beam 8 to deflect efficiently to reduce the deflection power.

In the above-described conventional pyramidal cathode ray tube, the cross section of the yoke mounting portion perpendicular to the tube axis has a straight inner and outer contour with two sides facing each other with the horizontal axis interposed therebetween, and is opposed with the vertical axis interposed therebetween. It can be seen that the inner and outer contours having one two sides are defined by convex curves protruding from the tube axis direction.

However, such a cathode ray tube has a curved position where the inflection point of the funnel and the yoke mounting portion is formed at the same coordinates with respect to the coaxial axis coordinates on the long axis, the short axis, and the diagonal axis, that is, when the outer shape of the yoke mounting portion is based on the diagonal axis, It is composed of a straight line, which reduces the maximum vacuum stress caused by atmospheric pressure by increasing the thickness of the long and short sides, but it increases the deflection power by increasing the thickness of the long and short sides, and also adjusts the front and rear of the deflection yoke. According to the deflection angle of the electron beam, the gap between the deflection coil and the electron beam is designed to be as far as the predetermined space between the outer surface of the funnel and the pyramidal deflection yoke, and thus there is a problem in that an optimization design for deflection sensitivity is not achieved.

In addition, since the inner contour of the yoke mounting portion is formed in the convex pincushion shape, it is difficult to secure the inner space relatively at the same outer contour size, and the thickness which is the difference between the inner and outer diameters is increased, thereby increasing the material cost and weight. there was.

Accordingly, an object of the present invention is to provide a cathode ray tube that maximizes the reduction of deflection power and the deflection sensitivity by bringing the magnetic field of the electron beam and the deflection coil as close to each other as possible according to the deflection angle of the electron beam. The outer surface contour of the yoke mounting portion has a constant curved pincushion along the X and Y axes according to the deflection angle of the electron beam based on the diagonal axis.

It is another object of the present invention to provide a cathode ray tube that increases the internal pressure strength while minimizing the thickness of the yoke portion, and this cathode ray tube uses tempered glass for thin portions in the X and Y axis directions of the yoke portion. It is characterized by healing.

It is still another object of the present invention to provide a cathode ray tube which enlarges the inner contour of the yoke mount to maximize the inner space of the yoke mount, and the cathode ray tube has a barrel shape in which the inner contour of the yoke mount is convex in the direction of the neck sealing surface. It is characterized by.

1 to 5 is a configuration diagram provided for the description of the color cathode ray tube according to the prior art,

1 is a perspective view of the color cathode ray tube seen from behind;

2 is a cross-sectional view along the tube axis of the color cathode ray tube,

3 is a cross-sectional view taken along line II of FIG. 1,

4 is a cross-sectional view taken along the line II-II of FIG. 1,

5 is a cross-sectional view corresponding to FIG. 4 for explaining the inner and outer surface shapes of the yoke mounting portion of the color cathode ray tube;

6 to 9 is a configuration diagram showing an embodiment provided for the description of the cathode ray tube according to the present invention,

6 is a perspective view of the cathode ray tube seen from behind;

7 is a cross-sectional view taken along line III-III of FIG. 6,

8 is a cross-sectional view taken along line IV-IV of FIG. 6,

FIG. 9 is a cross-sectional view taken along line VI-VI of FIG. 6, showing the upper half with respect to the tube axis.

<Description of the code | symbol about the principal part of drawing>

1: Effective part 2: Skirt part

3: panel 4: funnel

7: neck 8: electron beam

9: electron gun 10: vacuum outer container

100: yoke mounting portion 101: long side inflection point

102: diagonal inflection point 103: short side inflection point

104: long side 105, 107: curved surface

106: short side 113: deflection baseline

A cathode ray tube according to an aspect of the present invention for achieving the above object, at least a panel having a phosphor screen on the inner surface, a funnel connected to the panel, the end of the small diameter side of the funnel is bonded to the phosphor screen; In a cathode ray tube comprising a neck on which an electron gun is mounted, and a yoke-shaped yoke mounting portion extending from the end of the neck side to the panel side:

In the horizontal direction, the vertical axis, and the diagonal axis, the outer contour of the yoke mounting portion forming the boundary between the neck and the funnel is in the panel direction with respect to the tube axis while going in the direction of the horizontal axis and the vertical axis, based on the diagonal axis such that the contour of the yoke mount becomes a function of the deflection angle. It has a pincushion shape that increases gradually, the inner surface contour of the yoke mounting portion is characterized in that it has a substantially rectangular shape in which a pair of circular arcs having a center having a center on the horizontal axis, vertical axis and diagonal axis.

Optionally, when the pincushion amount on the horizontal axis with respect to the outer contour of the yoke mounting portion is Px and the pincushion amount on the vertical axis is Py, the pincushion amounts on the horizontal axis and the vertical axis are 0.05mm ≦ Px ≦ 2.5mm and 0.05mm ≦ Py ≦ Characterized in the range of 2.0mm.

Optionally, the range of the pin cushion with respect to the tube axis of the outer contour of the yoke mounting portion is such that the angle between the diagonal axis of the phosphor screen and the line connecting the point of the electron gun side on the screen of the tube axis is the angle of the deflection angle of the cathode ray tube. When the point on the tube axis that is 1/2 is the deflection reference line R / L, when the pincushion range on the horizontal axis is Wx and the pincushion range on the vertical axis is Wy based on the deflection reference line, R / L-20.0mm ≤ (Wx, Wy) ≤ R / L + 40.0mm It is characterized by.

In addition, according to the cathode ray tube of the present invention, at least a panel having a phosphor screen on the inner surface, a funnel connected to the panel, a neck joined to an end of the small diameter side of the funnel and mounted with an electron gun facing the phosphor screen, and the In a cathode ray tube consisting of a pyramidal yoke mounting portion extending from the neck end to the panel:

On the horizontal axis, the vertical axis and the diagonal axis, the outer surface contour of the yoke mounting portion forming the boundary between the neck and the funnel is in the panel direction with respect to the tube axis while going in the direction of the horizontal axis and the vertical axis based on the diagonal axis such that the contour of the yoke mounting becomes a function of the deflection angle. It has an approximately pincushion shape that increases gradually, and the inner surface contour of the yoke mounting portion has a substantially barrel-shaped shape that increases toward the neck sealing surface direction with respect to the tube axis while going in the direction of the vertical axis and the horizontal axis.

In addition, according to the cathode ray tube of the present invention, at least a panel having a phosphor screen on the inner surface, a funnel connected to the panel, a neck joined to an end of the small diameter side of the funnel and mounted with an electron gun facing the phosphor screen, and the In a cathode ray tube consisting of a pyramidal yoke mounting portion extending from the neck end to the panel:

When the point on the tube axis at which the angle between the diagonal line of the phosphor screen and the line on the electron gun side on the screen of the tube axis is half the deflection angle of the cathode ray tube is set to the deflection reference position, The yoke mounting portion outer surface shape of the cross section perpendicular to the tube axis at the deflection reference position is an approximately pincushion shape relative to the screen projecting in the tube axis direction, and the inner surface shape of the yoke mounting portion relative to the deflection reference position is toward the neck sealing surface. It is formed in the substantially barrel shape which increases.

As described above, when the outer surface shape of the yoke mounting portion on which the deflection yoke is mounted is used as the diagonal axis, the pincushion shape increases toward the panel axis with respect to the tube axis while the inner surface shape increases toward the neck sealing surface. By the barrel shape, it can be seen that the magnetic field of the electron beam and the deflection coil is close to and deflected.

As a result, the deflection power is effectively reduced while the internal pressure strength of the wide-angle vacuum exterior container is sufficiently secured, so that the deflection sensitivity is improved.

And, there may be a plurality of embodiments of the present invention, the following will be described in detail for the most preferred embodiment.

Through this preferred embodiment, the objects, other objects, features and advantages of the present invention will become more apparent from the following description with an embodiment according to the present invention in connection with the accompanying drawings shown for illustrative purposes.

Hereinafter, exemplary embodiments of the cathode ray tube according to the present invention will be described in detail with reference to the accompanying drawings.

In addition, the technique of the present invention can be applied to various image display apparatuses such as a color receiver, a color monitor, and the like.

In addition, in each figure used for description, the same component may be attached | subjected, and may show the same number, and the overlapping description may be abbreviate | omitted.

In the following description, an example of a color cathode ray tube, which is a video display device, is considered as a product for visually displaying an image.

6 is a perspective view of the color cathode ray tube of the present invention from behind, FIG. 7 is a cross-sectional view taken along line III-III of FIG. 6, and FIG. 8 is a cross-sectional view taken along line IV-IV of FIG. 6.

The color cathode ray tube according to this embodiment is provided with a vacuum outer container 10 made of glass.

The vacuum outer container 10 includes a panel 3 having a substantially rectangular shaped effective portion 1, a skirt portion 2 provided at the periphery of the effective portion, and a funnel-shaped funnel 4 bonded to the skirt portion 2. ) And a cylindrical neck 7 extending from this funnel.

The effective part 1 of the panel 3 is formed in the substantially rectangular shape which has the horizontal axis X and the vertical axis Y orthogonal to each other through the tube axis Z of a cathode ray tube.

The funnel 4 also has a small diameter portion, so-called yoke mounting portion 100, which extends toward the panel 3 side from the connection portion with the neck 7 to the position where the deflection yoke is mounted.

In particular, the yoke mounting portion 100 of the funnel 4 to which the deflection yoke in the color cathode ray tube is mounted is formed in a substantially pyramidal shape.

Specifically, the pyramidal yoke mounting portion 100 has a cross-sectional shape perpendicular to the tube axis Z in the vicinity of the connecting portion with the neck 7, but is circular in the same shape as the neck 7, but near the center along the tube axis Z direction. And in the vicinity of the end portion on the side of the phosphor screen 5, as shown in Figs.

As shown in FIG. 7 and FIG. 8, in the portion where the cross-sectional shape is formed in a substantially pincushion shape, the cross-sectional outer contour of the yoke mounting portion 100 has the horizontal axis X, in the horizontal, vertical, and diagonal directions of the effective portion 1. When having a vertical axis (Y) and a diagonal axis (D), a pair of curved surfaces 107 centered on the horizontal axis (X) and concave and a pair of curved surfaces 105 concave and centered on the vertical axis (Y) It forms the so-called pincushion shape which continued the circular arc 109 of the radius Rd which has the center in the vicinity of diagonal axis D.

In particular, the outer shape of the funnel 4 along the tube axis Z of the vacuum outer container 10 according to the invention is shown in FIGS. 6 and 9 in the funnel from the funnel 4 to the neck 7. It has an almost S-shape that is convex outward and concave to the neck side in the yoke mounting portion 100.

The boundary between the funnel 4 and the yoke mounting portion 100 is a long side inflection point 101, a diagonal inflection point 102, and a short side inflection point 103 for the long axis (X), the diagonal axis (D), and the short axis (Y) of the curve. )to be.

In addition, as shown in FIG. 9, the deflection yoke 6 is mounted so that the short edge 113 of the side of the panel 3 may be located in the vicinity of the diagonal inflection point 102, and the substantially yoke-shaped yoke mounting part 100 is At least from the connecting portion 111 with the neck 7 to the edge 113.

7 and 8 show the shape of the yoke mounting portion.

In the cross section of the yoke mounting portion 100 of Figs. 7 and 8, the inner surface is formed at the diagonal inflection point 102 with respect to the coordinates in the direction of the tube axis Z in the major axis X, the minor axis Y, and the diagonal axis D. The long side inflection point 101 and the short side inflection point 103 are formed differently so that the inner diameter Lap of the major axis extends from the connecting portion 111 with the neck 7 to the short edge 113 of the deflection yoke 6. It has an inner diameter Sap in the minor axis direction and an inner diameter dap in the diagonal axis direction.

In addition, the outer surface shape of the yoke mounting portion 100 has an outer diameter DAP and an inner diameter Lap in the diagonal axis D direction from the connecting portion 111 with the neck 7 to the short edge 113 of the deflection yoke. It has an outer diameter LAP in a longer major axis X direction and an outer diameter SAP in a shorter Y direction that is longer than an inner diameter Sap.

As shown in FIG. 8, the thickness of the yoke mounting part 100 is the diagonal axis D, the horizontal axis Y, and the vertical axis Y in the cross section of the tube axis Z which generally corresponds to the substantially deflection center called the deflection reference line 112. This is indicated by the difference between the inner and outer diameters (Lap, Sap) and (LAP, SAP) in the () direction.

In addition, the maximum vacuum stress is the maximum stress in the entire area of the yoke mounting portion 100, and in the case of the pyramidal yoke mounting portion 100, each part of the yoke mounting portion 100 on the side of the phosphor screen 5 is slightly smaller than the deflection reference line 112. The maximum stress in the tensile direction occurs.

As shown in FIGS. 7 and 8, the outer surface shape of the yoke mounting portion 100 is not a perfect plane but a pincushion shape that slightly protrudes in the tube axis (Z) direction, and thus, inner diameters (Lap, Sap), and (LAP). , SAP) has the thickness of long and short sides. That is, the outer surface shape of the yoke mounting portion 100 in the cross section orthogonal to the tube axis Z of the yoke mounting portion 100 is not a perfect rectangle, but each side is a curved surface that gently protrudes in the direction of the tube axis Z, so that the outer side of the yoke mounting portion 100 is It has a diameter (LAP, SAP).

In addition, the inner surface shape of the yoke mounting portion 100 in the cross section orthogonal to the tube axis Z of the yoke mounting portion 100 is not a perfect rectangle, but each side is a curved surface that gently protrudes toward the neck 7 sealing surface direction. It has the inner diameter (Lap, Sap) in the direction.

In addition, in the comparative examples of FIGS. 3 and 4 according to the related art and FIGS. 7 and 8 according to the present invention, when the diagonal axis D is used as a reference, the existing horizontal axis X and the vertical axis with respect to the tube axis Z are referred to. The outer diameters LA and SA of the present invention are smaller than the outer diameters LA and SA in the (Y) direction, and the existing horizontal axes X and the vertical axis ( It can be seen that the inner diameters Lap and Sap of the horizontal axis X and the vertical axis Y of the present invention are larger than the inner diameters La and Sa of the Y) direction.

Then, the short side 106 of the inner contour of the yoke mounting portion 100 is formed as a pair of curves having a radius centered on the horizontal axis X, as shown in Figs. Is formed as a pair of curves of radius centered on the vertical axis (Y).

As described above, when the long and short sides 104 and 106 of the inner contour of the yoke mounting portion 100 are formed in a gentle curve, the inner and outer diameters (Lap and LAP) in the horizontal axis (X) and vertical axis (Y) directions are formed. Due to the relatively thin thickness that is different from (Sap, SAP), each part is formed of curved arcuate surfaces 108 and 109 on both inner and outer surfaces, thereby sufficiently securing the inner space of the yoke mounting part 100. can do.

In particular, as shown in FIGS. 8 and 9, in the case of wide-angle deflection (cathode ray tube having a diagonal deflection angle of 95 degrees or more) having the shape of the pyramidal pyramidal yoke mounting portion 100, the front and rear adjustment of the deflection yoke 6 is performed. In the case of designing the inner surface of the deflection coil according to the deflection angle of the electron beam, the deflection power is low and the deflection sensitivity is improved because the deflection power is low when the electron beam is deflected close to the magnetic field of the electron beam and deflection coil. Therefore, as described above, the outer surface shape of the yoke mounting part 100 must be formed to be close to the horizontal axis X and the vertical axis Y so that a constant curved surface is formed so that a predetermined gap GAP exists between the inner surface of the deflection coil.

That is, the shape of the yoke mounting portion 100 in the present invention, as described above, the horizontal axis (X) and the vertical axis (Y) direction when the reference to the diagonal axis (D) so that the outer surface shape is a functional relationship with the deflection angle The increase in the direction toward the panel 3 with respect to the tube axis (Z) is formed as a pincushion type, the inner surface shape of the yoke mounting portion 100 in the horizontal axis (X) and the vertical axis (Y) direction with respect to the tube axis (Z) The neck 7 is formed in a substantially barrel shape which increases in the direction of the real name.

Here, when the pincushion amount on the horizontal axis (X) with respect to the outer surface of the yoke mounting portion 100 is Px and the pincushion amount on the vertical axis (Y) is Py, the pincushion amount (Px) on the horizontal axis is 2.5 mm or more from approximately 0.05 mm or more. The pincushion amount Py on the vertical axis is defined within the range of 0.05mm to 2.0mm.

By setting the pincushion amount in this way, the magnetic field of the deflection coils of the electron beam and the deflection yoke is close to that much, so that the power for deflecting the electron beam is reduced and the deflection sensitivity is improved.

In addition, as shown in FIG. 9, the range W of the pincushion with respect to the tube axis Z of the outer surface shape of the yoke mounting part 100 is in the diagonal screen of the phosphor screen 5, and the phosphor screen 5 of the tube axis Z. The deflection reference line 112 R / L is a deflection reference line 112 R / L where a point on which the straight line connecting the electron gun 9 side points with the tube axis Z is 1/2 of the deflection angle of the cathode ray tube. If the pincushion range on the horizontal axis (X) is Wx and the pincushion range on the vertical axis (Y) is Wy based on the reference line (R / L), then R / L-20.0mm ≤ (Wx, Wy) ≤ R / L + 40.0mm It is characterized by the range of.

At this time, as the thickness of the horizontal axis (X) and the vertical axis (Y) orthogonal to the tube axis (Z) of the yoke mounting portion (100) becomes relatively thin, the strength may be weakened at that portion, but tempered glass is used for this portion. It is also possible to sufficiently reinforce the atmospheric pressure strength.

As a result, in the thickness reduction rate of the outer surface and the inner surface of the yoke mounting portion 100 in the present invention, by reducing the thickness in the horizontal axis and the vertical axis direction with respect to the diagonal axis within the minimum limit that can withstand the pressure resistance, The magnetic field of the electron beam and the deflection yoke 6 is as close as possible, whereby the deflection power is reduced while the deflection sensitivity is improved.

On the other hand, as a comparative example, in the prior art, that is, the pyramidal yoke mounting portion based on the diagonal axis, the present invention is the outer surface of the yoke mounting portion to which the deflection yoke is mounted, unlike the outer surface shape having a constant linear shape. It can be seen that when the shape is based on the diagonal axis, the curved surface is given in the horizontal and vertical axis directions according to the deflection angle to maximize the deflection sensitivity influenced by the outer shape of the yoke mounting portion of the funnel.

As a result, according to the present invention, the outer surface of the yoke mounting portion of the funnel is almost approximated to the trajectory of the electron beam, and the inner surface is barrel-shaped to sufficiently secure the inner space, thereby ensuring sufficient deflection power while ensuring sufficient air pressure strength of the wide-angle vacuum exterior container. This is effectively reduced, and there is an advantage that the deflection sensitivity is improved.

As described above, in the present embodiment, the outer surface of the yoke mounting portion is pincushioned and the inner surface is barrel-shaped, so that no interference occurs in the electron beam deflection trajectory, and the distance between the electron beam and the magnetic field of the deflection yoke is increased. It can be optimized to reduce the deflection power and improve the deflection sensitivity.

In addition, although specific embodiments of the present invention have been described and illustrated above, it is obvious that the present invention may be variously modified and implemented by those skilled in the art.

Such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments should fall within the appended claims of the present invention.

It is clear from the above description that according to the cathode ray tube according to the present invention, in the case of the wide angle deflection cathode ray tube having the shape of a pyramidal yoke mounting portion, the inner surface of the deflection yoke according to the deflection angle of the electron beam during the forward and backward adjustment of the deflection yoke. When designing, the magnetic field of the electron beam and the deflection yoke are so close that the deflection power for deflecting the electron beam is effectively reduced, thereby improving the deflection sensitivity and maximizing the efficiency of the deflection yoke.

Claims (7)

A panel having at least a phosphor screen on the inner surface, a funnel connected to the panel, a neck joined to a small diameter end of the funnel and having an electron gun mounted thereon opposite the phosphor screen, and a pyramidal shape extending from the end of the neck side to the panel side; In a cathode ray tube consisting of a yoke mount of: In the horizontal direction, the vertical axis, and the diagonal axis, the outer contour of the yoke mounting portion forming the boundary between the neck and the funnel is in the panel direction with respect to the tube axis while going in the direction of the horizontal axis and the vertical axis, based on the diagonal axis such that the contour of the yoke mount becomes a function of the deflection angle. The cathode ray tube having an approximately pincushion shape that increases gradually, and the inner surface contour of the yoke mounting portion has an approximately rectangular shape in which a pair of arcs having a radius centered on the horizontal axis and the vertical axis is continuous. The method of claim 1, When the pincushion amount on the horizontal axis with respect to the outer contour of the yoke mounting portion is Px and the pincushion amount on the vertical axis is Py, the pincushion amount on the horizontal axis and the vertical axis is 0.05 mm ≤ Px ≤ 2.5 mm based on the diagonal axis. And 0.05 mm ≤ Py ≤ 2.0 mm. The method of claim 2, The range of the pin cushion with respect to the tube axis of the outer contour of the yoke mount is R / L when the deflection reference line is R / L, and when the pincushion range on the horizontal axis is Wx and the pincushion range on the vertical axis is Wy, based on the deflection reference line, A cathode ray tube, characterized in that it has a range of L / L-20.0mm ≦ Wx ≦ R / L + 40.0mm and R / L-20.0mm ≦ Wy ≦ R / L + 40.0mm. A panel having at least a phosphor screen on the inner surface, a funnel connected to the panel, a neck joined to a small diameter end of the funnel and having an electron gun mounted thereon opposite the phosphor screen, and a pyramidal shape extending from the end of the neck side to the panel side; In a cathode ray tube consisting of a yoke mount of: In the horizontal direction, the vertical axis, and the diagonal axis, the outer contour of the yoke mounting portion forming the boundary between the neck and the funnel is in the panel direction with respect to the tube axis while going in the direction of the horizontal axis and the vertical axis, based on the diagonal axis such that the contour of the yoke mount becomes a function of the deflection angle. It has an approximately pincushion shape that increases gradually, the inner surface contour of the yoke mounting portion has a substantially barrel-shaped shape that increases in the direction of the neck sealing surface with respect to the tube axis while going in the direction of the vertical axis and the horizontal axis. The method of claim 4, wherein When the point on the tube axis at which the angle at which the straight line connecting the point on the electron gun side on the screen of the diagonal screen of the phosphor screen and the electron gun side is 1/2 of the deflection angle of the cathode ray tube is set to the deflection reference line position, The outer surface contour of the yoke mount of the cross section perpendicular to the tube axis at the deflection reference line position is an approximately pincushion shape based on the screen projecting in the tube axis direction, and the inner surface contour of the yoke mount based on the deflection reference line toward the neck sealing face. A cathode ray tube, which is formed in an increasing barrel shape. The method of claim 5, The range of the pin cushion with respect to the tube axis of the outer contour of the yoke mounting portion is when the deflection reference line is R / L, when the pincushion range on the horizontal axis is Wx and the pincushion range on the vertical axis is Wy, based on the deflection reference line, A cathode ray tube, characterized in that it has a range of R / L-20.0mm ≦ (Wx, Wy) ≦ R / L + 40.0mm. The method of claim 5, When the pincushion amount on the horizontal axis with respect to the outer contour of the yoke mounting portion is Px and the pincushion amount on the vertical axis is Py, the pincushion amount on the horizontal axis and the vertical axis is 0.05 mm ≤ Px ≤ 2.5 mm, and 0.05 mm ≤ Py ≤ 2.0 mm. Cathode ray tube, characterized in that the range.