KR20000041070A - Cathode ray tube - Google Patents

Abstract

PURPOSE: A cathode ray tube is provided which reduces the maximum stress applied to a funnel by dispersing the stress concentrated at a starting part of a yoke installation part toward a sealing face of a neck. CONSTITUTION: A cathode ray tube has a vacuum exterior vessel(10) comprising a rectangular panel, a funnel(4) installed continuously to the panel and a cylindrical neck installed in a small diameter part of the funnel. The cathode ray tube comprises an electron gun(9) which emits an electron beam(8) toward a fluorescent screen, being installed in the neck, and a deflection yoke which deflects the electron beam emitted from the electron gun toward the horizontal axis and toward the vertical axis and scans the fluorescent screen by the electron beam. The funnel includes a yoke installation part(100) extended from the neck to a face panel(3).

Description

Cathode ray tube

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to cathode ray tubes such as color receiving tubes, color monitors, and the like, and more particularly to cathode ray tubes capable of effectively reducing deflection power while ensuring sufficient atmospheric pressure strength of a wide-angle vacuum outer container.

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.

On the other hand, in office automation (OA) devices such as personal computers (PCs), in which an operator approaches the cathode ray tube, a restriction on the leakage magnetic field leaking out of the cathode ray tube from the deflection yoke is tightened. As a means of reducing the magnetic field leaking out of the cathode ray tube in this deflection yoke, a method of adding a compensation coil is generally used. However, when the compensation coil is added in this way, the power consumption of the personal computer (PC) is increased.

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.

As an example of such a conventional cathode ray tube, a color cathode ray tube is shown in FIGS.

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

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

The effective part 1 of the face 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 face panel 3 side.

On the inner surface of the effective portion 1 of the face panel 3, stripe-shaped three-color phosphor layers 16B, 16G, and 16R emitting light in blue, green, and red, and A phosphor screen 5 made of a stripe-shaped light shielding layer 17 formed between the phosphor layers is provided.

Also, in the vacuum outer container 10, a shadow mask 11, which is a color screening electrode, is disposed opposite to the phosphor screen 5. The shadow mask 11 is provided with the mask body 18 which has many electron beam through-holes 19, and the mask frame 15 which supports the periphery of this mask body.

In addition, the shadow mask 11 is provided on the stud pins 14 which protrude from the inner surface of the skirt portion 2 of the face panel 3 to form a substantially wedge-shaped elastic support 13 on which corner portions of the mask frame 15 are fixed. It is supported by the face panel 3 by hanging.

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 shape having the same shape as that of the neck 7 as shown in FIG. 4 in the vicinity of the connection portion with the neck 7 whose cross section perpendicular to the tube axis Z is shown in FIG. 4. In the vicinity of the center portion along the Z) direction and near the end portion on the side of the phosphor screen 5, as shown in Figs. 5 and 6, the shape of the face panel 3 is substantially rectangular to match the shape of the effective portion 1.

As shown in FIG. 6, 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 in the horizontal, vertical, and diagonal direction of the effective part 1 contained in the face panel 3. As shown in FIG. (X), a vertical axis (Y), a diagonal axis (D), a pair of arcs 20 of a radius (Rx) centered on the horizontal axis (X) and a radius centered on the vertical axis (Y) A pair of circular arcs 21 of Ry and an arc 22 of a radius Rd having a center in the vicinity of the diagonal axis D are formed in a substantially rectangular shape.

In particular, the outer shape along the tube axis Z of the vacuum outer container 10 is convex outwardly from the funnel from the funnel 4 to the neck 7 and concave at the yoke mounting portion 12, as shown in FIG. The boundary between the funnel 4 and the yoke mounting portion 12 having an S curve is the inflection point 28 of the curve.

The deflection yoke 6 is mounted such that the end edge 27 on the face panel side is located near the inflection point 28, and the yoke mounting portion 12 is substantially at the end edge from the connection 30 with the neck 7 at least. It becomes (27). And the inflection point 28 of the outer contour of the funnel 4 is formed with the same coordinates in the coordinates in the tube axis Z direction with respect to the horizontal axis X, that is, the major axis and the vertical axis Y, that is, the minor axis and the diagonal axis D.

The shape of the yoke attachment part 12 is shown in FIG. 9 and FIG.

In the cross section of the yoke mounting portion 12 in FIG. 9, the inner surface shape is formed by the inflection points 28 of the major axis X, the minor axis Y, and the diagonal axis D having the same coordinates in the coordinates of the tube axis Z direction. And the inner diameter la in the major axis direction and the inner diameter sa in the minor axis direction from the connecting portion 30 to the neck 7 to the short edge 27 of the deflection yoke 6.

In addition, the curve 31 in FIG. 10 shows the outer diameter DA in the direction of the diagonal axis D from the connection portion 30 with the neck 7 to the screen side end of the deflection yoke 6, that is, the end edge 27. , The curve 32 is the outer diameter LA in the major axis direction longer than the inner diameter la, and the curve 33 is the outer diameter SA in the minor axis direction longer than the inner diameter sa.

As shown in the curves 31 to 33, the yoke mounting portion 12 has a circular shape having substantially the same shape as that of the neck 7 in the connecting portion 30 with the neck 7 as shown in FIG. 5) As it moves toward the side, with respect to the outer diameter DA in the diagonal axis D direction, the inner and outer diameters la, sa (LA, SA) in the major axis and the minor axis direction change so as to gradually decrease, and the tube axis Z The shape in the cross section perpendicular to) becomes almost rectangular (semi-circular shape).

In this case, the aspect ratio M: N of the phosphor screen 5 is 4: 3.

In addition, the thickness of the yoke mounting part 12 is generally in the direction of the diagonal axis D, the horizontal axis X, and the vertical axis Y in the cross section of the tube axis Z corresponding to the approximately deflection center called the deflection reference line 29. , The external diameters (la, sa) and (LA, SA) are represented by the difference.

In addition, the maximum vacuum stress is the maximum stress in the entire area of the yoke mounting portion 12, and in the case of the pyramidal yoke mounting portion 12, the angle of the yoke mounting portion 12 on the side of the phosphor screen 5 is slightly smaller than the deflection reference line 29. The maximum stress in the tensile direction is generated at each portion.

That is, in other words, as shown in Figs. 5, 6 and 9, the inner surface shape of the yoke mounting portion 12 is not a plane but a pincushion shape projecting in the observation (Z) direction, and the inner and outer diameters la, It has the thickness (T1, T2) of the long and short sides by the difference between sa) and (LA, SA). 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 12 is not a perfect rectangle but a convex curve in which each side protrudes in the direction of the tube axis Z. It has an inner diameter of la and sa.

And the short side 24 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 25 is formed in a convex curve having a top on the vertical axis (Y) have.

In the case where the long and short sides 25 and 24 of the inner contour are convex curves, the angles due to the difference between the inner and outer diameters la and sa and LA and SA in the major axis and the minor axis direction ( In order to avoid the extreme fall of the thickness in the vicinity of the part (i), each part is formed with the arc-shaped curved surface, ie, the arc (22, 26) surface on both the inner surface and the outer surface.

The inner contour shape of the yoke mounting portion 12 and the thicknesses T1 and T2 of the long side and the short side are set in accordance with the shape of the electron beam passing region 23 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 23, so that the inner surface of the yoke mounting portion 12 is the electron beam passing region 23. 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 23 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. 7, 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 If (θ) is assumed, the inner contour of the yoke mounting portion 12 has the maximum or 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 not forging with a 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 inner surface of the yoke mounting portion 12 is formed by making the yoke mounting portion 12 of the funnel 4 into a substantially rectangular shape in its outer cross section and a curved shape in which each side of the inner contour is convex in the tube axis direction. The electron beam passing region 23 can be made close to each other, and the thicknesses T1 and T2 of the yoke mounting portion 12 in the vicinity of the vertical axis and the horizontal axis can be thickened to improve the strength of the yoke mounting portion. Therefore, the atmospheric pressure strength of the vacuum outer container 10 can be raised, and the deflection yoke can be improved, thereby reducing the deflection power.

In the above-described cathode ray tube according to the prior art, the cross section of the yoke mounting portion perpendicular to the tube axis has an outer contour of a substantially rectangular shape having two opposite sides with the horizontal axis interposed and two opposite sides with the vertical axis interposed therebetween. A convex curve having a substantially rectangular inner contour having two opposite sides with a horizontal axis interposed therebetween and a two opposite side with a vertical axis interposed therebetween, with a portion of each side of the inner contour of the cross section projecting toward the tube axis. It can be seen that it is prescribed by.

However, in the conventional cathode ray tube as described above, the inflection point positions of the funnel and the yoke mounting portion are formed in the same coordinates with respect to the coordinates in the tube axis direction on the major axis, the short axis, and the diagonal axis, that is, the inner surface shape of the yoke mounting portion is formed in a pincushion shape. Although the maximum vacuum stress caused by atmospheric pressure is reduced by increasing the thickness of the long and short sides, the current color cathode ray tube technology is developed to be 100 degree deflection rather than the conventional 90 degree deflection as a method of reducing the electric field length. When the thickness of the long and short sides is increased on the cross section of the tube axis, a neck shadow is generated on the inner surface of the yoke mounting portion, thereby causing a shadow on the phosphor screen.

In addition, since the inner contour of the yoke mounting portion has a convex shape inwardly, it is difficult to secure the internal space relatively at the same outer contour size, and the thickness that is the difference between the inner and outer diameters is increased, thereby increasing the material cost and weight. .

In addition, the stress concentration in the funnel due to the wide angle becomes particularly large, and considering the neck shadow, the maximum vacuum strength is increased, which may cause firecrackers in the exhaust during the manufacturing process, and reliability in the explosion-proof test after the cathode ray tube is completed. There are inherent disadvantages that cannot be guaranteed.

Therefore, a cathode ray tube capable of suppressing the occurrence of neck shadow caused by an increase in the thickness of the yoke mounting portion in the vicinity of the vertical axis and the horizontal axis with respect to the tube axis, and sufficiently reducing the internal pressure strength of the vacuum outer container, while reducing the deflection power, is preferable. .

Accordingly, the present invention eliminates the stress concentrated on the yoke mounting portion of the funnel due to the neck shadow and wide angle of the neck shadow generated on the inner surface of the yoke mounting portion in accordance with the increase in the thickness of the long and short sides on the cross section of the tube axis. It is an object of the present invention to provide a cathode ray tube for dispersing the stress concentrated at the start point of the yoke mounting portion in the direction of the sealing surface of the neck to reduce the maximum stress applied to the funnel.

In another aspect of the present invention, the inflection points of the long axis, short axis, and diagonal axis are formed at different positions in the coordinates in the tube axis direction to sufficiently secure the pressure resistance of the wide-angle vacuum exterior container and effectively reduce the deflection power. There is a purpose.

As another aspect of the present invention, the purpose is to sufficiently secure the inner space of the yoke mounting portion to suppress the occurrence of the neck shadow.

1 to 9 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 a colored 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 perspective view schematically showing an electron gun, a phosphor screen, and a shadow mask of the color cathode ray tube,

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

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

6 is a cross-sectional view taken along line III-III of FIG. 1,

7 is a cross-sectional view corresponding to FIG. 6 for explaining the inner and outer surface shapes of the yoke mounting portion of the color cathode ray tube;

FIG. 8 is a cross-sectional view taken along line IV-IV of FIG. 1, showing the upper half of the tube axis.

FIG. 9 is a simplified view showing a cross section of the quarter side of FIG. 6 for explaining the inner and outer surfaces of the yoke mounting portion of FIG. 1;

10 is a curve diagram illustrating the shape of the yoke mounting portion of the color cathode ray tube of FIG. 1;

11 to 15 are configuration diagrams showing an embodiment provided for the description of the color cathode ray tube according to the present invention.

11 is a perspective view from behind of the color cathode ray tube according to the present invention;

12 is a cross-sectional view taken along the line VV of FIG. 10,

FIG. 13 is a cross-sectional view taken along line VI-VI of FIG. 11, showing the upper half of the tube axis.

13A is a cross-sectional view for illustrating a diagonal inflection point.

13B is a cross-sectional view for illustrating a long side inflection point.

13C is a cross-sectional view for illustrating a short side inflection point,

14 is a simplified cross-sectional view of the quarter side in FIG.

FIG. 15 is a curve diagram illustrating the shape of the yoke mounting portion of FIG. 11. FIG.

<Description of Symbols for Main Parts of Drawings>

1: Effective part 2: Skirt part

3: face panel 4: funnel

7: neck 8: electron beam

9: electron gun 10: vacuum outer container

100: yoke mounting portion 101: deflection yoke

102: deflection reference line 103: short edge of the deflection yoke

104: connecting portion 105: diagonal inflection point

106: long side inflection point 107: short side inflection point

109: long side 111: short side

Cathode ray tube according to an aspect of the present invention for achieving the above object, the face panel having a substantially rectangular effective portion having a horizontal, vertical orthogonal to each other via a tube axis, funnel-shaped funnel bonded to the face panel A vacuum outer container having a cylindrical neck bonded to a small diameter end of the funnel, and a phosphor screen formed on an inner surface of the effective portion of the face panel;

An electron gun installed in the neck to emit an electron beam toward the phosphor screen; And

A deflection yoke mounted outside the yoke mounting portion of the neck and the funnel and deflecting the electron beam emitted from the electron gun in the horizontal and vertical axis directions and scanning the phosphor screen by an electron beam; A yoke mounting portion extending from the end to the face panel;

In a color cathode ray tube having a non-circular shape in which the outer contour of at least one cross section perpendicular to the tube axis of the yoke mounting portion has a non-circular shape such that the distance between the outer contour and the tube axis is maximum between the vertical axis direction and the horizontal axis:

When the contour of the outer surface of the funnel forming the boundary between the neck and the funnel on each axis is based on the diagonal axis near the position of the yoke mounting portion, the long and short side inflection points of the outer contour become closer to the respective axes. It is characterized by having a shape positioned to increase in the sealing surface direction.

Optionally, the distance from the diagonal inflection point to the long inflection point with respect to the horizontal axis is ΔH, and the distance from the diagonal inflection point to the short inflection point with respect to the vertical axis, based on the diagonal inflection point with respect to the diagonal axis through the tube axis. In the case of ΔV, the ratio of ΔH to ΔV is defined as ΔH / ΔV ≦ 3/4.

Optionally, the range of the distance ΔH from the diagonal inflection point to the long inflection point is defined as 30 mm ≧ ΔH ≧ 3 mm.

Preferably, the short inflection point is located in the neck sealing surface direction more than the long inflection point when positioned based on the diagonal inflection point.

Further, according to the cathode ray tube of the present invention, at least one cross section perpendicular to the tube axis is maximized in the vertical axis direction and the horizontal axis direction of the screen, from the neck connection position of the yoke mounting portion to at least the screen side end of the deflection yoke. A semi-circular shape having an outer diameter of the yoke mounting portion, and a straight line connecting a point of the electron gun side on the screen of the screen diagonal end and the tube axis forms an angle with the tube axis, and the angle on the tube axis is 1/2 of the deflection angle with the cathode ray. When is taken as the deflection reference position,

The yoke mount inner surface shape cross section of the cross section perpendicular to the tube axis at the deflection reference position is a substantially rectangular shape relative to the screen that does not protrude in the tube axis direction, and is a funnel sealing of the diagonal inflection point of the yoke mount based on the deflection reference position. The long side and the short side inflection point toward the surface, characterized in that formed differently positioned toward the neck sealing surface.

In this way, it can be seen that the stress concentrated at the start point of the yoke mounting portion is dispersed in the direction of the sealing surface of the neck, so that the maximum stress applied to the funnel is reduced and the inner space of the yoke mounting portion can be more effectively secured.

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 demand for high luminance and high frequency deflection is satisfied.

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 addition, the following description considers an example of a color cathode ray tube which can be called an image display device as a product which visually displays an image.

FIG. 11 is a perspective view from behind of the color cathode ray tube of the present invention, FIG. 12 is a cross-sectional view taken along the line VV of FIG. 10, and FIG. 13 is a cross-sectional view taken along the line VI-VI of FIG. The upper half is shown.

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 face panel 3 having an almost rectangular effective portion 1 and a skirt portion 2 provided at the periphery of the effective portion, and a funnel-shaped funnel joined to the skirt portion 2. 4) and a cylindrical neck 7 extending from the funnel.

The effective part 1 of the face 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 101 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 where the deflection yoke 101 is mounted. It has a small diameter part and what is called a yoke mounting part 100 extended toward the face panel 3 side.

In particular, the yoke mounting portion 100 of the funnel 4 to which the deflection yoke 101 is mounted in the color cathode ray tube 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 FIG. 12, a substantially rectangular shape is matched to the shape of the effective portion 1 of the face panel 3.

As shown in FIG. 12, 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 100 is a horizontal axis (X) and a vertical axis (Y) in the horizontal, vertical, and diagonal direction of the effective part (1). , A pair of arcs having a center R on the vertical axis Y and a pair of arcs centering on the vertical axis Y, having a diagonal axis D, It forms the substantially rectangular shape which continued the 108 and the circular arc 112 of the radius Rd centered in the vicinity of the diagonal axis D. As shown in FIG.

In particular, the outer shape of the funnel 4 along the tube axis Z of the vacuum outer container 10 according to the present invention is shown in FIGS. 11 and 13 in the funnel from the funnel 4 to the neck 7. A substantially S-shaped curve is convex outward and concave to the neck side at the yoke mounting portion 12.

The boundary between the funnel 4 and the yoke mounting portion 12 is a diagonal inflection point 105, a long inflection point 106, and a short inflection point 107 with respect to the diagonal axis D, the long axis X, and the short axis Y of the curve. )to be.

In addition, the deflection yoke 101 is mounted such that the short edge 103 on the side of the face panel 3 is located near the diagonal inflection point 105, and the yoke mounting portion 100 is substantially connected to the neck 7 at least. 104 to the short edge 103. The diagonal inflection point 105, the long side inflection point 106, and the short side inflection point 107 are formed at different positions in the coordinates in the tube axis Z direction with respect to the long axis, short axis, and diagonal axis.

14 and 15 show the shape of the yoke attachment portion.

In the cross section of the yoke mounting portion 100 of FIG. 14, the inner surface shape is a long side inflection point 106 and a short side inflection point with respect to the coordinates in the direction of the tube axis Z in the long axis X, the short axis Y, and the diagonal axis D. 107, the diagonal inflection point 105 is formed at different positions so that the inner diameter in the major axis direction (lap) from the connecting part 104 to the short edge 103 of the deflection yoke 101 and the inner diameter in the minor axis direction (sap) And an inner diameter dap in a diagonal direction.

That is, as shown in FIG. 13A, the diagonal inflection point 105 on the diagonal axis is formed by being positioned upward of the funnel 4 rather than the position of the existing inflection point 28, and has long and short inflection points 106 and 107. ) Is positioned toward the neck 7 as shown in Fig. 13 (b, c).

In FIG. 15, the curve 114 is the outer diameter DAP in the diagonal axis D direction from the connecting portion 104 with the neck 7 to the short edge 103 of the deflection yoke 101, and the curve 115. ) Is a long axis outer diameter (LAP) longer than the inner diameter (lap), the curve 116 is a short axis outer diameter (SAP) longer than the inner diameter (sap).

As shown in the curves 114 to 116, the yoke mounting portion 100 has a circular shape having almost the same shape as the neck on the connecting portion 104 with the neck 7, but is moved closer to the phosphor screen 5 side. As the reference to each axis is closer to each axis, the long side inflection point 106 and the short side inflection point 107 of the outer contour change so as to increase toward the neck 7 sealing surface and the shape in the cross section perpendicular to the tube axis Z is changed. It is almost rectangular.

In particular, as shown in Figs. 11 and 13, when the distance from the diagonal inflection point 105 to the long side inflection point 106 is ΔH and the distance from the diagonal inflection point 105 to the short side inflection point 107 is ΔV, The ratio of ΔH and ΔV is defined as ΔH / ΔV ≤ 3/4.

More preferably, the ratio of the distance is defined as ΔH / ΔV = 3/4. In this case, the maximum stress due to atmospheric pressure was found to be most efficiently reduced.

In addition, the range of the distance (DELTA) H from the diagonal inflection point 105 to the long side inflection point 106 is prescribed | regulated as 30 mm <=> H <3> mm.

The thickness of the yoke mounting portion 100 is the inner and outer diameters of the diagonal axis (D), horizontal axis (Y), and vertical axis (Y) directions in the cross section of the tube axis (Z) corresponding to the center of deflection generally referred to as the deflection reference line 102. It is represented by the difference of (lap, sap) and (LAP, SAP).

In addition, the maximum vacuum stress is the maximum stress in the entire region 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 102. The maximum stress in the tensile direction occurs.

As shown in Figs. 12 and 14, the inner surface of the yoke mounting portion 100 is not a perfect plane but a substantially rectangular shape that slightly protrudes in the direction of the tube axis (Z). The inner diameters (lap, sap), (Lap, It has the thickness of long and short sides by the difference of SAP). That is, the inner contour of the yoke mounting portion 100 in the cross section perpendicular to the tube axis Z of the yoke mounting portion 100 is not a perfect rectangle, but each curve is a curve in which the sides gently protrude in the direction of the tube axis Z, and thus the inside of the long and short axis directions. It has a diameter (lap, sap).

In addition, as can be seen from the comparative example of Fig. 9 according to the prior art and Fig. 14 according to the present invention, the existing horizontal and vertical outer diameters LA and SA with respect to the tube axis Z and the horizontal and vertical directions of the present invention. The outer diameter (LAP, SAP) of the same size, but the inner diameter (lap, sap) of the present invention is secured larger than the existing inner diameter (la, sa).

As a result, the diagonal inflection point 105, the long side inflection point 106, and the short side inflection point 107 are formed at different positions with respect to the tube axis Z, so that the inner and outer diameters (lap, sap) and (LAP, SAP) Since the thickness of the difference is reduced, the internal space of the yoke mounting portion 100 can be efficiently secured.

12 and 14, the short side 111 of the inner contour of the yoke mounting portion 100 is formed in a curve having a gentle top portion on the horizontal axis X, and each of the long sides 109 has a vertical axis ( It is formed as a curve with a gentle top on Y).

As described above, when the long and short sides 109 and 111 of the inner contour are formed in a gentle curve, the thickness that is different from the inner and outer diameters (lap, sap) and (LAP, SAP) in the major and minor axes is Due to the thinning, each of the inner and outer surfaces may be formed of arcuate surfaces 112 and 113 having substantially rectangular shapes, thereby securing an inner space of the yoke mounting portion 100.

As a result, the long and short inflection points 106 and 107 of the outer contour of the yoke mounting portion 100 are closer to each axis when the position of the yoke mounting portion 100 is based on the diagonal axis D. By increasing the configuration toward the sealing surface, the stress concentrated at the starting point of the funnel is dispersed in the sealing surface direction of the neck, and as a result, the maximum stress applied to the funnel is reduced.

On the other hand, as a comparative example, the inflection point of the outer surface contour of the yoke mounting portion of the conventional technology, that is, the funnel is formed at the same coordinates in the coaxial axis direction with respect to the long axis and the short axis diagonal axis, and the yoke mounting portion is extended on the cross section of the tube axis. Unlike increasing the thickness of the short side to improve the air pressure strength of the vacuum outer container, the present invention forms the inflection point positions of the outer contour of the yoke mounting portion at different positions with respect to the long axis, the short axis, and the diagonal axis, so as to be caught by the funnel. It can be seen that the maximum stress is reduced.

As a result, according to the present invention, by dispersing the stress concentrated at the start point of the yoke mounting portion in the direction of the sealing surface of the neck to reduce the stress applied to the funnel, the internal pressure strength of the wide-angled vacuum external container is sufficiently secured and also deflected. There is an advantage that the power can be effectively reduced.

As described above, in the present embodiment, the inflection point of the outer contour of the yoke mounting portion is increased toward the sealing surface of the neck as it approaches each axis when the diagonal axis is a reference, so that no neck shadow is generated on the inner surface of the yoke mounting portion. In addition, the stress in the funnel according to the wide angle is dispersed to ensure the atmospheric pressure strength of the vacuum outer container.

According to this application example, the inflection points of the outer contour of the yoke mounting portion of the funnel are formed at different positions, whereby the pressure resistance of the vacuum outer container is sufficiently secured and the reliability of the cathode ray tube can be improved.

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, the inflection point positions of the outer contour of the yoke mounting portion on which the deflection yoke is mounted are formed at different positions in the tube axis direction, whereby the thicknesses of the long and short sides are reduced. It is advantageous to secure the inner space of the yoke mounting portion, and also brings the effect of weight reduction and material cost reduction.

In addition, the atmospheric pressure strength of the wide-angle vacuum exterior container is sufficiently secured, and the deflection power is effectively reduced, thereby satisfying the requirements of high luminance and high frequency deflection.

Claims (4)

A face panel having an almost rectangular shape effective portion having a horizontal and a vertical direction perpendicular to each other through a tube axis, a funnel-shaped funnel bonded to the face panel, a cylindrical neck bonded to a small diameter end of the funnel, and the A vacuum outer container having a phosphor screen formed on an inner surface of an effective part of the face panel; An electron gun installed in the neck to emit an electron beam toward the phosphor screen; And A deflection yoke mounted outside the yoke mounting portion of the neck and the funnel and deflecting the electron beam emitted from the electron gun in the horizontal and vertical axis directions and scanning the phosphor screen by an electron beam; A yoke mounting portion extending from the end to the face panel; In a cathode ray tube wherein the funnel has a yoke mount of approximately rectangular cross section: The yoke mounting portion and the funnel has an inflection point at the junction and the cathode ray tube, characterized in that the position of the inflection point is different with respect to the diagonal axis, long axis and short axis. The method of claim 1, A distance from the diagonal inflection point to the long inflection point with respect to the horizontal axis is ΔH and the distance from the diagonal inflection point to the short inflection point with respect to the vertical axis is ΔV when the diagonal inflection point with respect to the diagonal axis is referred to through the tube axis. Wherein the ratio of ΔH to ΔV is defined as ΔH / ΔV ≤ 3/4. The method according to claim 1 or 2, A cathode ray tube, characterized in that the range of the distance (ΔH) between the diagonal inflection point and the long side inflection point is defined as 30 mm≥ΔH≥3 mm. The method of claim 3, wherein The cathode ray tube of claim 1, wherein the short side inflection point is increased in the direction of the neck sealing surface than the long side inflection point based on the diagonal inflection point.