JP3565057B2 - Color picture tube equipment - Google Patents

Description

【００３３】
表１に示すように、従来の曲線が９つのパラメータで表されるのに対し、本発明は６つ、Ｘ’とＹ’を除けば実質４つのパラメータで表される。また、図４中、曲線４１（実線）が本発明の曲線を示し、曲線４２（破線）が従来の曲線を示している。３つの円を組み合わせた従来のものより、単一の関数で表される本発明の方が曲線がなめらかなものとなっていることがわかる。
【００３４】
Ｚ＝−２０と同様にして、Ｚ＝−１０、０、１０の各位置におけるパラメータを求めた結果を表２に示す。
【００３５】
【表２】

【００３６】
そして、Ｚ軸方向の関数としてａ（Ｚ）、ｂ（Ｚ）、ｎ（Ｚ）を作成することでコイル形状全体を決定できる。上記４点のパラメータを用い、コンピュータを用いて多項式にフィッティングした一例を示す。
【００３７】

ただし、各定数は表３に示すとおりである。
【００３８】
【表３】

【００３９】
なお、▲１▼式においてパラメータＸ’、Ｙ’は曲線を管軸から偏心させる場合に用いるパラメータであり、偏向ヨーク７の中心軸とファンネル４の管軸とをずらす場合に０以外の値をとる。これらを用いても合計５つのパラメータでコイルを設計することができる。
【００４０】
【発明の効果】
以上説明したように、本発明によれば、偏向ヨークの設計の工数およびその精度を大幅に向上させ、さらに、なめらかなコイル曲面を描かせて巻線バラツキを少なくすることができ品質の優れたカラー受像管を得ることができる。
【図面の簡単な説明】
【図１】本発明のカラー受像管装置の側面図
【図２】同じくファンネルおよび偏向ヨークの側面断面図
【図３】同じく水平偏向コイルのＺ軸断面図
【図４】水平偏向コイル外曲面の第１象限におけるＺ軸断面図
【図５】従来の水平偏向コイルのＺ軸断面図
【符号の説明】
１ カラー受像管装置
４ ファンネル
７ 偏向ヨーク
１０ 水平偏向コイル
３１ 内曲面
３２ 外曲面[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a color picture tube device used for a television, a computer display, and the like, and particularly to a shape of a deflection yoke.
[0002]
[Prior art]
Japanese Patent Publication No. 48-34349 discloses an in-line type color picture tube using a funnel having a rectangular tube axis cross section instead of a circular tube in order to reduce the deflection power of the deflection yoke. If the funnel shape of the portion where the deflection yoke is mounted is changed from a cylindrical shape to a rounded square shape, the distance from the horizontal deflection coil and the vertical deflection coil of the deflection yoke to the electron beam can be reduced, so that the deflection power can be reduced. Can be reduced.
[0003]
In general, the curve forming the outer funnel curved surface in the tube axis section of the square funnel is composed of three arc portions in one quadrant. That is, assuming that a pipe axis passing through the center of the screen surface is a Z axis, a horizontal axis is an X axis, a vertical axis is a Y axis, and a diagonal axis of the screen surface is a diagonal axis, the X axis is near any X axis cross section. Is composed of an arc centered on the X-axis (hereinafter referred to as “long-axis circle”), and a curve near the diagonal axis is an arc centered on the diagonal axis (hereinafter called “diagonal-axis circle”). ), And the curve near the Y axis is an arc centered on the Y axis (hereinafter referred to as “short axis circle”). Then, these three circles are combined to form a rounded square shape as a whole. Therefore, the Z-axis cross-sectional shape of the outer curved surface of the rectangular funnel is given by a function using the radius of the major axis circle, the minor axis circle, the radius of the diagonal axis circle, and the respective center positions as parameters.
[0004]
Conventionally, the deflection yoke mounted on such a square funnel also has the same Z-axis cross-sectional shapes of the inner curved surface (the funnel side surface) and the outer curved surface of the horizontal deflection coil, the vertical deflection coil, and the ferrite core as the outer curved surface of the funnel. , A long axis circle, a short axis circle, and a diagonal axis circle. For example, since the inner curved surface of the horizontal deflection coil has a shape substantially following the funnel shape, it is almost the same as the outer curved surface of the funnel, and the radius of the long axis circle, the short axis circle, and the diagonal axis circle is 0 to 1 [mm]. ] Degree is added.
[0005]
FIG. 5 shows a cross-sectional shape in the first quadrant (as viewed from the screen side) of a Z-axis cross section of a conventional horizontal deflection coil. The following nine parameters determine the inner curved surface 31.
[0006]
Center coordinate of long axis circle (WL1LX, WL1LY)
Radius of long axis circle WR1L
Center coordinates of short axis circle (WL1SX, WL1SY)
Radius of short axis circle WR1S
Center coordinates of diagonal axis circle (WL1DX, WL1DY)
Radius of diagonal axis circle WR1D
The shape of the outer curved surface of the horizontal deflection coil is designed in consideration of the magnetic field distribution and the cross-sectional area of the Z-axis cross section of the horizontal deflection coil. In the magnetic field distribution, a shape is required such that the coil thickness increases as approaching the X axis so that a pincushion magnetic field of a self-convergence magnetic field can be generated. Therefore, it is necessary to make the center coordinate of the long axis circle closer to the origin side and determine the long axis circle radius so that the cross-sectional area of the horizontal deflection coil in the Z-axis cross section can secure a desired copper wire area. Further, it is necessary to determine the radius and the center position of the short axis circle so that the coil thickness in the short axis direction is smaller than the thickness in the long axis direction. Further, the diagonal axis circle needs to have an appropriate coil thickness in the diagonal axis direction while being in contact with the two circles of the long axis circle and the short axis circle. The following nine parameters determine the outer curved surface 32.
[0007]
Center coordinate of long axis circle (WL2LX, WL2LY)
Radius of long axis circle WR2L
Center coordinates of short axis circle (WL2SX, WL2SY)
Radius of short axis circle WR2S
Center coordinates of diagonal axis circle (WL2DX, WL2DY)
Radius of diagonal axis circle WR2D
As described above, the shape function of the horizontal deflection coil is designed in consideration of the funnel shape, the magnetic field distribution, and the cross-sectional area of the coil in the Z-axis cross section. Similarly, regarding the vertical deflection coil, the shape of the horizontal deflection coil, the magnetic field distribution, and the cross-sectional area of the coil in the Z-axis cross-section are taken into consideration in a comprehensive manner. And the center position of each axis circle are determined, and the shape function of the coil is designed.
[0008]
[Problems to be solved by the invention]
As described above, the Z-axis cross-sectional shape at the Z position where the horizontal deflection coil and the vertical deflection coil are located has a rectangular shape by combining three circles of a long axis circle, a short axis circle, and a diagonal axis circle. Therefore, the functions of the radius and the center position of the three circles must be determined for the inner curved surface and the outer curved surface, respectively. Since one coil requires as many as 18 parameters, the design is complicated, and there has been a problem that the number of design steps is greatly increased as compared with a conical funnel having a circular cross section.
[0009]
In addition, since the connection between the three circles must be smooth, not only does the design add complexity, but also the connection between the three circles has a limit in obtaining the same smoothness as in each circle. There were also problems.
[0010]
Moreover, such a design has to be performed for each of the inner and outer curved surfaces of the horizontal deflection coil, the inner and outer curved surfaces of the vertical deflection coil, and the inner and outer curved surfaces of the ferrite core, and the labor is enormous.
[0011]
The present invention has been made in order to solve such a problem, and can easily, quickly, hardly cause a mistake, and realize a desired magnetic field distribution and a coil cross-sectional area with a small number of design parameters. An object of the present invention is to provide a high-quality color picture tube in which the accuracy can be greatly improved, a smooth coil curved surface can be realized, the coil winding is performed smoothly, and there is little variation.
[0012]
[Means for Solving the Problems]
The color picture tube device of the present invention is a color picture tube device in which a deflection yoke is mounted on the outer surface of a funnel, and one or all of a horizontal deflection coil, a vertical deflection coil, and a ferrite core constituting the deflection yoke are provided. One or both of the Z-axis cross-sectional shapes of the inner curved surface and the outer curved surface are represented by a single function in each of the first to fourth quadrants, and the function is as follows in the first quadrant. (Claim 1).
{(XX ′) / a｝ ⁿ + {(Y−Y ′) / b} ^m = 1
(However, a, b, n, and m are constants. N and m are not constant along the Z axis.)
[0014]
Further, in the color picture tube device according to claim 1 , a Z-axis cross section of a portion of the outer curved surface of the funnel on which the deflection yoke is mounted has an arc centered on the X axis and a diagonal axis. an arc having a center, is made of three arcs of a portion of a circular arc having a center on the Y-axis (claim 2).
[0015]
The present invention, with the above configuration, can easily, quickly, hardly cause errors, achieve the desired magnetic field distribution and coil cross-sectional area with less design parameters than before, can significantly improve the man-hour and accuracy of coil design, In addition, a smooth coil curved surface can be realized, the coil winding can be performed smoothly, and a high quality color picture tube with little variation can be realized.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described with reference to the drawings.
[0017]
FIG. 1 shows a color picture tube device of the present invention. In the color picture tube device 1, a front panel 3 having a phosphor screen surface 2 formed on an inner surface thereof and a funnel 4 constitute an envelope. An electron gun 6 is installed in a neck portion 5 of the funnel 4, and a funnel 4 is provided. The deflection yoke 7 is mounted on the outer surface of the.
[0018]
FIG. 2 shows a side cross section of the deflection yoke 7. The deflection yoke 7 includes a horizontal deflection coil 10 provided along the outer curved surface of the funnel 4, a vertical deflection coil 11 provided outside the horizontal deflection coil 10, and insulation for insulating the horizontal deflection coil 10 from the vertical deflection coil 11. The frame 12 includes a ferrite core 13 provided outside the vertical deflection coil 11 and a correction coil 14 provided on the electron gun side.
[0019]
FIG. 3 shows a Z-axis cross section of the horizontal deflection coil 10 provided in the deflection yoke 7. The horizontal deflection coil 10 has a coil formed by an inner curved surface 31 and an outer curved surface 32.
[0020]
Hereinafter, a description will be given of an example in which the present invention is applied to a 46 mm (19 inch), 100 degree-deflection color picture tube device.
[0021]
Consider the shape of the first quadrant of the Z-axis cross section at a position (Z = -20) of 20 [mm] from the reference line 8 of the color picture tube toward the electron gun (Z = -20). Here, the “reference line” refers to a reference position for determining the deflection angle θ of the electron beam 9 as shown in FIG. 1, and the dimension (46 cm) of the phosphor screen surface 2 and the deflection angle θ (100 [゜]). The outer curved surface of the funnel 4 at this position is represented by the following nine parameters (unit [mm]).
[0022]
Center coordinate of long axis circle (WL1LX, WL1LY) = (-4.38347,0)
Radius of long axis circle WR1L = 21.09326
Center coordinate of short axis circle (WL1SX, WL1SY) = (0, -6.364422)
Radius of short axis circle WR1S = 22.20382
Center coordinate of diagonal circle (WL1DX, WL1DY) = (5.80665, 4.35664)
Radius of diagonal axis circle WR1D = 10.0109
Along the outer curved surface of the funnel 4, the inner curved surface 31 of the horizontal deflection coil 10 is transformed into a function {(XX ′) / a｝ ⁿ + ｛(Y−Y ′) / b} ^m = 1.・ ▲ 1 ▼
, Each parameter is as follows.
[0023]
X '= Y' = 0
a = 16.70979
b = 15.83960
n = 2.35
m = 2.35
Next, how to obtain these parameters will be described.
[0024]
X ′ and Y ′ are X ′ = Y ′ = 0 when the Z axis of the funnel 4 and the central axis of the deflection yoke 7 are coincident.
[0025]
a and b are determined in correspondence with the X-axis intercept a ′ and the Y-axis intercept b ′ on the outer curved surface of the funnel 4. In consideration of the combination allowance of the funnel 4 and the deflection yoke 7,
a = a '+ α
b = b '+ α
(However, α = 0 to 1.0 [mm]). The above values are for α = 0,
a = -4.38347 + 21.09326 + 0 = 16.70979
b = −6.36242 + 22.2030382 + 0 = 15.89360
Is required.
[0026]
n and m are parameters that determine the distance from the Z-axis cross-sectional center O in the diagonal axis direction, and are determined along the outer curved surface of the funnel 4 in the diagonal axis direction. Specifically, using a and b determined as described above, giving appropriate n and m, draw a curve with a computer, and changing the n and m little by little, the curve that best fits the funnel outer curved surface Are determined visually to determine n and m.
[0027]
Next, a method for determining the parameters when the outer curved surface 32 of the horizontal deflection coil 10 is expressed by an equation will be described. In the case of the inner curved surface 31, as described above, the shape may simply be along the outer curved surface of the funnel 4, whereas in the case of the outer curved surface 32, a design that meets the requirements from the characteristic surface of the deflection coil is required. It becomes.
[0028]
a and b represent the intersections of the curve with the X axis and the Y axis, respectively. Therefore, by increasing a, it is possible to secure a coil thickness necessary to emphasize the pincushion magnetic field of the horizontal deflection coil 10. Conversely, b is set smaller than a.
[0029]
n and m are parameters that determine the distance from the center O of the Z-axis cross section in the diagonal axis direction. If n and m are large, the distance from the center O to the coil diagonal becomes large. In order to reduce and adjust the high-order magnetic field distortion in the diagonal axis direction while being along the outer curved surface of the funnel 4, n and m are determined so as to reduce the coil thickness at this portion. The specific calculation method is the same as in the case of the inner curved surface 31.
[0030]
As described above, for the outer curved surface 32 of the horizontal deflection coil 10, an optimal curved surface can be obtained by appropriately adjusting the parameters a, b, n, and m. An example of the parameter is shown below.
[0031]
X '= Y' = 0
a = 20.53167
b = 18.82967
n = 2.25
m = 2.25
Table 1 and FIG. 4 show an example of the outer curved surface 32 of the horizontal deflection coil 10 comparing the conventional one with the present invention.
[0032]
[Table 1]

[0033]
As shown in Table 1, the conventional curve is represented by nine parameters, whereas the present invention is represented by six, and substantially four parameters except for X 'and Y'. In FIG. 4, a curve 41 (solid line) indicates a curve of the present invention, and a curve 42 (dashed line) indicates a conventional curve. It can be seen that the curve of the present invention represented by a single function is smoother than the conventional one in which three circles are combined.
[0034]
Table 2 shows the results of obtaining parameters at each position of Z = −10, 0, and 10 in the same manner as for Z = −20.
[0035]
[Table 2]

[0036]
Then, by creating a (Z), b (Z), and n (Z) as functions in the Z-axis direction, the entire coil shape can be determined. An example in which the above four parameters are used to fit a polynomial using a computer will be described.
[0037]

However, each constant is as shown in Table 3.
[0038]
[Table 3]

[0039]
In the formula (1), parameters X 'and Y' are parameters used when the curve is decentered from the tube axis. When the center axis of the deflection yoke 7 and the tube axis of the funnel 4 are shifted, values other than 0 are set. Take. Using these, a coil can be designed with a total of five parameters.
[0040]
【The invention's effect】
As described above, according to the present invention, the man-hour and accuracy of the design of the deflection yoke are greatly improved, and furthermore, the winding variation can be reduced by drawing a smooth coil curved surface, and the quality is excellent. A color picture tube can be obtained.
[Brief description of the drawings]
FIG. 1 is a side view of a color picture tube device of the present invention. FIG. 2 is a side sectional view of a funnel and a deflection yoke. FIG. 3 is a Z-axis sectional view of a horizontal deflection coil. FIG. FIG. 5 is a sectional view of a Z-axis in a conventional horizontal deflection coil in the first quadrant.
Reference Signs List 1 color picture tube device 4 funnel 7 deflection yoke 10 horizontal deflection coil 31 inner curved surface 32 outer curved surface

Claims (2)

A color picture tube device in which a deflection yoke is mounted on an outer surface of a funnel, wherein one or all of a horizontal deflection coil, a vertical deflection coil, and a ferrite core constituting the deflection yoke have one of an inner curved surface and an outer curved surface or A color picture tube device wherein both Z-axis cross-sectional shapes are represented by a single function in each of the first to fourth quadrants, and the functions are as follows in the first quadrant .
{(XX ′) / a} ⁿ + {(Y−Y ′) / b} ^m = 1
(However, a, b, n, and m are constants. N and m are not constant along the Z axis.) Of the outer curved surface of the funnel, the Z-axis cross section of the portion where the deflection yoke is mounted has an arc centered on the X axis, an arc centered on the diagonal axis, and an arc centered on the Y axis. 2. The color picture tube device according to claim 1, comprising three arc portions.

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