KR100467830B1 - Deflection yoke and method improving inner pin using thereof - Google Patents

Abstract

The present invention relates to a deflection yoke. More specifically, the magnet 100 is attached within ± 15 ° of the left portion along the X axis (horizontal axis) of the screen portion 22 of the coil separator 20 to increase the deflection force. As described above, the present invention improves the characteristics by minimizing the difference of the inner pin unbalance through the bending adjustment on the set in the state where the biasing force is increased to the left part of the screen, thereby improving the characteristics. There is no need to use, thereby reducing the unit cost of the deflection yoke +368 and improving the product competitiveness.

Description

Deflection yoke and method improving inner pin using clearly

The present invention relates to a deflection yoke, and more particularly, to a deflection yoke and a method of improving an inner pin using the same without using an inner pin module by using a magnet.

Recently, the trend of the display market is to make the screen flat, large, high definition, low power, and slim to increase the efficiency by reducing the installation space.

Similarly, TV receivers and monitors, which are one of the display devices, are being developed in the direction of flat screen, large size, high definition, low power, and slim. In particular, power consumption can be lowered to meet the enhanced environmental standards. There is a demand for a high quality display device capable of enlarging an effective screen.

Generally, the principle of electron beam deflection scanned from an electron gun is applied to a cathode ray tube (hereinafter referred to as a CRT) constituting a TV receiver or a monitor. In order to scan an electron beam, horizontal and vertical directions of the cathode ray tube Deflection field must be applied.

Coils for making this deflection magnetic field are referred to as horizontal and vertical deflection coils. Basically, they are combined at right angles to each other, and the deflection yoke is composed of the horizontal deflection coil and the vertical deflection coil and a ferrite core.

FIG. 1 shows an example of a conventional CRT. Referring to this, the conventional CRT has a screen panel 1 having a fluorescent film emitting three colors on its inner surface, and a frit glass fused to a rear end of the screen panel. A funnel 2 forming internal vacuum, an electron gun 5 mounted in the neck portion 7 at the rear end of the funnel and emitting electron beams 4a, 4b and 4c, and an electron beam 4a and 4b emitted from the electron gun. ) And a deflection yoke 6 for deflecting 4c) from side to side on the front screen.

The deflection yoke 6 has a vertical deflection coil (not shown) which applies a vertical deflection magnetic field to the electron beams 4a, 4b and 4c emitted from the electron gun of the cathode ray tube and deflects the electron beam in the vertical direction, and the electron beam 4a. ) And (b) a horizontal deflection coil (not shown) which deflects the electron beam in the horizontal direction by applying a horizontal deflection magnetic field to (4b) and (4c), and precisely distinguish the positions of the horizontal deflection coil and the vertical deflection coil, and electrically mutually. A coil separator (not shown) to enable insulation and a ferrite core (not shown) to enhance the magnetic field through horizontal and vertical deflection coils.

The screen panel 1 of the conventional CRT shown in FIG. 1 is a round panel used in a conventional CRT. Since the screen panel 1 is curved to protrude toward the front of the screen, the deflection yoke ( In 6), the deflection distance from the top of the screen to the fluorescent surface of the screen did not differ significantly from the top, center, or bottom of the screen, so that distortion did not occur significantly.

That is, as shown in Fig. 1, since the conventional screen panel 1 is a round type, the deflection distance A of the electron beam 4a emitted to the upper side of the screen and the deflection distance of the electron beam 4b emitted to the center of the screen are shown. The distance difference between B and the deflection distance C between the electron beam 4c emitted to the lower side of the screen is not large, and therefore, distortion in the screen is not large.

However, as the trend of the display market in recent years, as described above, in order to flatten the screen constituting the panel of the screen portion flat, as shown in Figure 2, the screen panel 11 is made of a flat surface.

Since the deflection distance from the deflection yoke 16 to the fluorescent surface of the screen panel 11 is different from the top, the center, and the bottom of the screen, the STI is equipped with the flat screen panel 11 such that distortion occurs. It became.

That is, as shown in FIG. 2 while the screen panel 11 is planarized, the deflection distance A 'of the electron beam 14a emitted to the upper side of the screen and the deflection distance C' of the electron beam 14c emitted to the lower side of the screen, and As the distance difference between the deflection distance B 'of the electron beam 14b emitted to the center is large, a problem of distortion occurs.

As the difference between the deflection distances A ′ and C ′ of the upper and lower portions of the screen and the deflection distance B ′ of the center occurs as described above, an inner pin phenomenon due to distortion is observed in the front of the screen, as shown in FIG. 3. This will occur.

Generally, deflection yoke creates pincushion type magnetic field with horizontal deflection coil and barrel type magnetic field with vertical deflection coil to form screen pattern as a whole.In general round panel, inner pin is formed due to curvature of CRT. Little or no cushion distortion appears with the naked eye.

However, in the case of the flat CRT, the inner pincushion appears due to less correction of the vertical pincushion distortion in the middle part of the center and the left and right outermost points of the screen.

FIG. 3 is a front view showing the inner pin phenomenon in a conventional flat panel, and the inner pin phenomenon is a solid line in the drawing. This means pincushion distortion that bends inside of the screen in the middle.

That is, when the inner pin phenomenon occurs, the image is bent inward due to the difference in the deflection distance between the center and the upper and lower portions of the screen, so that the quality of the screen may be degraded, and thus a high quality CRT may not be provided.

Therefore, as indicated by the dotted lines in FIG. 3, it is most preferable that the vertical lines of the screen appear in a vertical line shape so as to connect the top, center, and bottom of the screen in a straight line.

On the other hand, to improve the inner pin phenomenon, conventionally, an additional circuit is used in the deflection yoke 16, which is called an inner pin module.

In other words, the inner pin module is an additional circuit that can eliminate the inner pin phenomenon to compensate for vertical pincushion distortion in a horizontal deflection coil that creates a pincushion type magnetic field.

4 shows a typical inner pin module.

Referring to this, in general, the inner pin module is provided with a vertical correction coil 21 wound around a core 20 positioned at an intermediate portion thereof, and cores 22 and 24 positioned on both sides of the vertical correction coil are opposite to each other. The horizontal correction coils 23 and 25 are wound so as to generate a magnetic field, and the cores to which the horizontal correction coils are wound are provided such that permanent magnets 26 and 27 are attached to the outside.

The inner pin module configured as described above is operated by induction electromotive force by mutual inductance of the vertical correction coil 21 and the horizontal correction coil 23 and 25, so that the horizontal correction coil creates a pincushion type magnetic field. Vertical pincushion distortion can be corrected.

That is, when a fixed magnetic field is generated in the direction of the arrow F1 by the permanent magnets 26 and 27, and current flows in the horizontal correction coils 23 and 25 in this state, one horizontal correction coil 23 The magnetic field generated at) is generated in the opposite direction to the fixed magnetic field as indicated by arrow F2, and the magnetic field generated at the other horizontal correction coil 25 is the same as the fixed magnetic field as indicated by arrow F3. Is caused by.

Therefore, the magnetic field generated in this way makes the screen size smaller in the middle part, the screen sizes are equal in the center parts on the left and right, and the inner pin distortion of the middle left and right is corrected on the screen.

However, when using a separate inner pin module to correct the inner pins as described above, there was a disadvantage in that the cost of the product increased.

In other words, in order to survive the endless competition with LCD, CRT technology needs to improve the quality and reduce the unit price. However, when the inner pin module is used, the unit price increases and the product competitiveness decreases.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object thereof is to attach a magnet to a portion of the coil separator so that the characteristics of the inner pin unbalance on the screen can be improved without using an inner pin module. To provide a deflection yoke.

Another object of the present invention to provide an inner pin improvement method using the deflection yoke.

The deflection yoke according to the present invention for achieving the above object is formed integrally by the screen portion and the neck portion, the magnet is attached to improve the characteristics of the inner pin unbalance by increasing the deflection force on a portion of the outer surface of the screen portion Coil separator; A horizontal deflection coil which is assembled to be divided into upper and lower sides around an inner circumference of the connecting portion of the coil separator to form a horizontal deflection magnetic field; Vertical deflection coils are assembled to be divided into left and right around the outer peripheral portion of the coil separator to form a vertical deflection magnetic field; And a ferrite core assembled to surround the vertical deflection coil to reinforce the deflection magnetic field.

And, it is preferable that the magnet has a magnetic flux density of 10 gauss.

In addition, the magnets are symmetrically attached to the upper and lower sides of the X axis within ± 15 ° of the left portion with respect to the X axis (horizontal axis) of the coil separator.

In addition, the magnet forms a groove in the coil separator and is inserted into and attached to the groove.

Inner pin improvement method using the deflection yoke according to the present invention for achieving the above another object is to increase the deflection force to the left portion of the screen by attaching a magnet to the left portion along the X axis (horizontal axis) of the coil separator screen portion The difference between the inner pin unbalance is minimized by the bending adjustment on the set so that the last left line and the last right line of the screen are in a straight line.

And, it is preferable that the magnet has a magnetic flux density of 10 gauss.

In addition, the magnets are symmetrically attached to the upper and lower sides of the X axis within ± 15 ° of the left portion with respect to the X axis (horizontal axis) of the coil separator.

In addition, the magnet forms a groove in the coil separator and is inserted into and attached to the groove.

1 is a side view showing an example of a cathode ray tube equipped with a general round screen panel;

2 is a side view showing an example of a cathode ray tube equipped with a general flat screen panel;

3 is a front view illustrating an inner pin phenomenon occurring in a general flat screen panel;

4 is a cross-sectional view showing an example of a general inner pin module;

5 is a side view showing a deflection yoke according to the present invention;

6 is an exploded perspective view of a magnet showing a part of a coil separator in a deflection yoke according to the present invention;

7 is a front view of the coil separator in the deflection yoke according to the present invention;

8 is a view schematically showing an effective screen of a cathode ray tube to explain a position to which a deflection yoke is applied according to the present invention;

9 is an operation diagram sequentially showing a method for improving the screen in the cathode ray tube to which the deflection yoke is applied according to the present invention.

◎ Explanation of symbols for main part of drawing

10: deflection yoke 20: coil separator

22: screen portion 22a: home

24: neck portion 30: vertical deflection coil

40: ferrite core 50: adhesive

100: magnet a: final left line

b: left line c: center line

d: right line e: final right line

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 5 is a side view showing a deflection yoke according to the present invention, Figure 6 is a perspective view of a magnetic separation showing a part of the coil separator in the deflection yoke according to the invention, Figure 7 is a front view showing a coil separator in the deflection yoke according to the present invention. to be.

Referring to this, the deflection yoke 10 according to the present invention is provided with a coil separator 20 and horizontal deflection coils (not shown) which are formed around the inner and outer circumferences of the coil separator 20 to form a horizontal deflection magnetic field and a vertical deflection magnetic field, respectively. C) and vertical deflection coils 30, and a ferrite core 40 for enhancing the magnetic field of the horizontal and vertical deflection coils.

The coil separator 20 distinguishes the positions of the vertical and horizontal deflection coils and at the same time electrically insulates them. The screen part 22 is provided on the screen surface side of the cathode ray tube, and the electron gun side of the cathode ray tube. A cylindrical neck portion 24 coupled to the electron gun portion is provided, and the screen portion and the neck portion are integrally connected by a fallopian tube-shaped connecting portion.

In addition, a magnet 100 is attached to a portion of the screen portion 22 of the coil separator radar 20 to increase the deflection force to improve the characteristics of the inner pin unbalance.

Here, it is preferable that the magnets 100 are symmetrically attached to the upper and lower sides of the X axis within ± 15 ° of the left portion with respect to the X axis (horizontal axis) of the coil separator 20.

However, the magnet 100 may be attached to only one side of the coil axis 20 with respect to the X axis within ± 15 ° of the left portion with respect to the X axis (horizontal axis) of the coil separator 20.

That is, the magnet 100 may be attached to at least one, but it is important that the magnet position is attached within ± 15 ° of the left portion relative to the X axis (horizontal axis) of the coil separator 20.

Here, the left part of the coil separator 20 refers to a position corresponding to the left part of the screen as shown in FIG. 8.

The magnet 100 is preferably configured to have a magnetic flux density of 10 gauss.

In other words, if the magnetic flux density of the magnet 100 is lower than 10 gauss, the improvement of the inner pin unbalance is insignificant. If the magnetic flux density is higher than 10 gauss, the improvement of the inner pin unbalance is good. It is desirable to.

In addition, the magnet 100 can be attached directly to the screen portion 22 of the coil separator 20, but the groove 22a is formed in the screen portion 22 of the coil separator 20 and the groove is formed in the groove portion 22 of the coil separator 20. It is preferable to insert and attach the magnet 100.

In addition, the magnet 100 is preferably made of a rubber material.

On the other hand, the inner side of the coil separator 20 is assembled to be in close contact with the horizontal deflection coil divided into upper and lower sides, and the outer side is assembled to be in close contact with the vertical deflection coil 30 divided into left and right, the deflection coil is It is fixed so as not to flow through the hot melt adhesive (50).

In addition, a ferrite core 40 for reinforcing the vertical deflection magnetic field is assembled to surround the vertical deflection coil 30 on the outer circumference of the coil separator 20.

Now, a method for improving inner pin unbalance by applying the deflection yoke according to the present invention configured as described above will be described.

First, the magnet 100 is attached to the screen portion 22 of the coil separator 20 along the X axis (horizontal axis), as shown in FIG. 8, and the magnet is disposed on the left portion of the effective screen. Has the effect.

Therefore, the deflection force is increased to the left part on the screen due to this magnet 100.

In this state, if the bending adjustment is performed on the set so that the last left line and the last right line of the screen are in a straight line, there is a difference in the inner pin unbalance.

For better understanding, a method of improving a screen will be described in detail with reference to the accompanying FIG. 9.

First, the inner pin unbalance on the screen typically appears as shown in the figure.

That is, a pin of about 0.3 mm is generated on the left side of the center line c, while a straight line is maintained on the left line b based on the center line, while a pin of about 0.7 mm is on the right line d. Is generated.

Therefore, since the pin difference between the left line b and the right line d exceeds 0.7 mm, a distortion phenomenon occurs.

At this time, the final left line (a) and the last right line (e) also maintain a straight line.

When the magnet 100 having the magnetic flux density of 10 gauss is placed on the left part as shown in the figure (b) on the screen having the inner pin unbalance, the final left line a has a barrel of about 0.3 mm ( barrel) is generated, and a pin of about 0.3 mm is generated on the final right line e to appear on the screen.

In this state, if the final left line (a) and the last right line (e) are adjusted to be in a straight line through the bending adjustment on the set, (c) as shown in the drawing, the center line (c) changes to a straight line, and the center line On the basis of this, a pin of about 0.3 mm is generated in the left line b, and a barrel of about 0.3 mm is generated in the right line d to maintain a pin of about 0.4 mm.

Therefore, since the pin difference between the left line b and the right line d is reduced to 0.1 mm, the characteristics of the inner pin unbalance are improved.

As such, the present invention can improve the inner pin unbalance with only the magnet 100 without using a conventional inner pin module.

As described above, the present invention does not require the use of a conventional inner pin module because the inner pin unbalance is easily improved by using a magnet, thus reducing the unit cost of the deflection yoke and improving the product competitiveness.

Claims (10)

A coil separator having a screen portion and a neck portion integrally formed by a connecting portion, and having a magnet attached to a portion of the outer surface of the screen portion to increase the biasing force to improve the characteristics of the inner pin unbalance; A horizontal deflection coil which is assembled in an upper circumference and a lower part around an inner circumference of the connection part of the coil separator to form a horizontal deflection field; A vertical deflection coil assembled around the outer side of the connecting portion of the coil separator in a left and right direction to form a vertical deflection magnetic field; And Deflection yoke characterized in that it comprises a ferrite core is assembled to surround the vertical deflection coil to strengthen the deflection magnetic field. The method of claim 1, And said magnet has a magnetic flux density of 10 gauss. The method according to claim 1 or 2, The magnets are deflected yokes, characterized in that the magnets are attached symmetrically to the upper and lower sides of the X axis within ± 15 ° of the left portion with respect to the X axis (horizontal axis) of the coil separator. The method according to claim 1 or 2, The magnet is a deflection yoke, characterized in that attached to only one side of the X axis within ± 15 ° of the left portion relative to the X axis (horizontal axis) of the coil separator. The method of claim 1, And said magnet is provided with a groove formed in the screen portion of said coil separator and inserted into and attached to said groove. With the magnet attached to the left part along the X axis (horizontal axis) of the coil separator screen, the deflection force is increased to the left part of the screen, and the bending is adjusted on the set so that the last left line and the last right line of the screen are in a straight line. Method for improving the inner pin of the deflection yoke, characterized by minimizing the difference in pin unbalance. The method of claim 6, And said magnet has a magnetic flux density of 10 gauss. The method according to claim 6 or 7, The magnets are improved in the inner pin of the deflection yoke, characterized in that the magnets are attached symmetrically to the upper and lower sides of the X axis within ± 15 ° of the left portion with respect to the X axis (horizontal axis) of the coil separator. The method according to claim 6 or 7, The magnet is a pin yoke improvement method of the inner pin of the deflection yoke, characterized in that attached to only one side of the X axis within ± 15 ° of the left portion relative to the X axis (horizontal axis) of the coil separator. The method of claim 6, And the magnet is provided with a groove formed in the screen portion of the coil separator and inserted into and attached to the groove.