KR20010096726A - A magnet assembly for convergence with magnet of unbalace polarity - Google Patents

Abstract

PURPOSE: A magnet assembly for convergence where a magnet with an asymmetric polarity is formed is provided to increase a fine tuning which improves a productivity by minimizing fabrication costs and thus to improve an economical efficiency of the whole CRT(Cathode Ray Tube) convergence. CONSTITUTION: According to the convergence, three magnet rings(10,20,30) of P polarity, 4 polarity and 6 polarity forming a magnetic pole with two sheets and one pair and a spacer(40) intervened between each magnet ring to block an interference of the magnet rings are inserted in sequence into a nonmagnetic holder(50). And a spacer magnetized with additional asymmetric even polarity above two polarity which can control a CCV(Centerside Convergence Value) and an OCV(Outside Convergence Value) at the same time by inducing a displacement of side beams(R beam, B beam) among R, G, B beam when each magnet ring is in a minimum magnetic state is intervened in a fixed place of the magnet assembly.

Description

MAGNET ASSEMBLY FOR CONVERGENCE WITH MAGNET OF UNBALACE POLARITY

The present invention relates to a magnet assembly for convergence in which a magnet of asymmetric polarity is installed on a neck portion of an inline type color picture tube (CPT).

More specifically, the red beam (R) and the blue beam (B) are used to artificially disperse the arrangement of the electron beam of the cathode ray tube (CRT) with a very small focusing error in fine tuning and static focusing with each magnet ring pair. ), The magnet magnetized by a spacer magnetized with two or more asymmetric even poles to induce one side beam and two side beams of the green beam G to simultaneously adjust the outside convergence value (OCV) and the centerside convergence value (CCV). By interposing the assembly, a pair of four-pole magnets to enhance the OCV and a pair of six-pole magnets to enhance the CCV in one artificial operation to induce the R, B, G beam, 2 It is possible to improve production productivity by minimizing the manufacturing cost by making one spacer into one spacer to improve manufacturing assembly. Which will not only to improve the economic efficiency of cathode-ray tubes the convergence of the convergence magnet assembly to improve the fine-tuning to maximize efficiency.

A typical cathode ray tube (CRT) includes a deflection yoke (DY) and a convergence (PCM) as a means for deflecting and adjusting an electron beam by coupling an electron gun to an exhausted glass tube as shown in FIG.

The color picture tube (CPT) is coupled to the neck of the cathode ray tube (CRT) and three electron guns are installed transversely so that the cathode ray generated from each electron gun is red beam (R), green beam (G) and blue beam on the screen. It appears as (B).

At this time, the R, G, B beams are designed to be emitted from the electron gun and connected to one point of the shadow mask, but according to the manufacturing process of the cathode ray tube (CRT) and the manufacturing process of the color picture tube (CPT) Due to manufacturing errors, it is impossible to obtain a uniform product, and it is almost impossible to statically focus on a point as desired.

Therefore, a certain focusing deviation is inevitably generated, and a convergence has been developed and used to adjust this deviation to focus on one point statically.

The convergence includes a pair of magnets magnetized with P-poles, 4-poles, and 6-poles. The conventional convergence displaces the electron beam emitted by Fleming's left hand law and Lorentz force.

On the other hand, the deflection yoke (DY) is composed of a ferrite core, a pair of vertical deflection coils and a pair of horizontal deflection coils and is operated by a separate power source to generate a magnetic field, and the magnetic field deflects the electron beam to form the entire screen. The raster is scanned on the surface of the beam, which is also called beam rotation in which both side beams (R and B beams) bend in a bow shape with respect to the center beam (G beam) due to a manufacturing error of the deflection yoke. Phenomena occur, and four-pole madneting is added to compensate for this.

The beam rotation phenomenon caused when the statically focused beams are formed as a raster over the entire screen is positioned as a pair of magnets magnetized into four poles and corrected on a horizontal one axis line.

The deflection yoke DY and the convergence PCM may be integrally formed or used separately.

As shown in FIG. 2, in the R, G, and B beams to be statically focused on the mechanical center, which is the center point of the cathode ray tube (CRT), the magnet ring magnetized to the P-pole is dispersed R, G, B The beam (see "ga") is displaced by the same distance in the same direction, and the G beam, which is the center beam of the electron beams, is adjusted to be located at the mechanical center (see "b").

Thereafter, the R beam and the B beam, which are the side beams, are collected using the magnet pole of the four poles while maintaining the position of the G beam, which is the center beam (see "C"), wherein the four poles are the side beams. The R and B beams are displaced by the same distance in opposite directions, and when the R and B beams are closely adjusted, the magnets of six poles are adjusted to move the R and B beams to both sides of the G beam. R beams, G beams, and B beams are statically focused in the mechanical center side by side (see "D").

At this time, the above work process is called ITC (Integrated Tube Component) work. In this case, in the static focusing using the 4 poles and 6 poles, the linear separation distance between the R beam and the B beam (“OCV”) is 4 poles. The center distance of the linear separation distance (OCV) between the R beam and the B beam and the linear separation distance (called "CCV") between the G beams are adjusted to six poles so that the three beams are statically focused at one point.

However, as described above, the magnetization of the convergence for statically focusing the three electron beams R, G, and B at one point is also difficult to manufacture in an ideal state, so that there is little focusing error of each beam or a minute error. In the case of error-free tubes, they cause adverse reactions.

That is, as shown in FIG. 3, the pair of magnet rings may have the N pole and the S pole opposite to each other so as to form a minimum magnetic field that is a canceled state of the magnetic field in order to minimize the displacement amount of each beam during the initial coupling. Is formed.

In this case, in the case of the error-free tube, the electron beam B1 focused at one point on the shadow mask according to the design value should not be affected by the minimum magnetic field of the converged magnet assembly, which is ideally manufactured (that is, the beam must not move). It is easy to adjust.

However, in the case of a convergent magnet assembly which is not ideally manufactured, the electron beam B1 is displaced like the electron beam B2 (i.e., the beam moves), which causes considerable difficulty in adjustment.

Accordingly, the convergence magnet assembly in such error free tubes requires a technique for minimizing the amount of electron beam shift at the minimum magnetic field.

In the related art, various types of technologies have been developed and extracted to manufacture a converged magnet assembly requiring such characteristics.

That is, the focus has been on reducing the deviation between the north pole and the south pole of each magnet ring, and in recent years, the combination of the magnet rings has a difference in the mean magnetic flux density of each magnetic pole or a pair of magnet rings with the north pole. This is the difference in magnetic flux density of the S pole.

The minimum beam displacement (shift amount) at the minimum of the composite magnetic field, which makes a difference in the average magnetic flux density of each magnet ring, is 0.2-0.5mm, and the minimum beam displacement is still large at 0.1-0.8mm at the maximum of the magnetic field. When the combined magnetic field of each pair of magnet rings is maximized, there is a problem that the center beam G is moved a considerable amount, making adjustment difficult.

In addition, the difference between the magnetic flux density of the N pole and the S pole in the single magnet ring is 0.2-0.8mm minimum beam displacement at the minimum of the composite magnetic field and 0.1-0.8mm at the center beam displacement at the maximum of the composite magnetic field. The minimum beam displacement is not negligible, and when the composite magnetic field of each pair of magnets is maximized, the central beam is displaced considerably, making the static focusing composition more difficult.

On the other hand, according to the conventional technique, the difference in the mean magnetic flux density of each pair of magnet rings, that is, a pair rate of about 10-30%, is applied to the inlet side magnet ring and the outlet side magnet ring of the beam and the inlet side The magnet ring is formed so that the average magnetic flux density is larger than that of the outlet magnet ring. In this case, the magnet ring used at the inlet side and the magnet ring to be used at the outlet side should be magnetized separately in consideration of the pair ratio. In addition to the problem of having to sort and assemble the inlet side and the outlet side, respectively, in the roaming and assembling process, it is difficult to identify with the naked eye and sometimes has a problem of providing a defect factor due to misassembly.

In addition, even in the case of an ideally manufactured convergence magnet assembly using the above-described technique, the amount of beam shift in the absence of magnetic field is necessarily present due to the scattering of the convergence magnet assembly.

Therefore, when statically concentrating three beams of an error-free tube with very small amount of OCV and CCV at one point, the ITC adjustment is very narrow and the operation is not easy due to the error of OCV and CCV generated in the minimum magnetic field. The magnetic field difference of the magnetic poles, that is, the pair rate is used in the present situation.

Meanwhile, a separate magnetic pole is formed in each of the two spacers provided between the magnet rings, and the four-pole magnetizer spacer and the side beams (R beam and B beam) are moved to the left and right sides of the side beams (R beam and B beam). However, static condensation is performed by forming a six-pole magnetized spacer for displacing the beam by moving it up and down, but there is a problem in that cost increase and assembly work for producing two spacers separately are not easy.

As a result, there is always a problem that the productivity and economical efficiency of the overall cathode ray tube convergence are reduced due to the above problems and the efficiency is minimized.

The present invention has been made to solve the problems occurring in the related art as described above, and has the following objects.

The present invention artificially disperses the arrangement of electron beams of a cathode ray tube (CRT) having a very small focusing error in adjusting static focusing with each magnet ring pair of cathode ray tube convergence installed in the neck portion of an inline type color picture tube (CPT). Spacer magnetized by two or more asymmetric even-poles to adjust OCV and CCV simultaneously by inducing one side beam and both side beams among red beams (R), blue beams (B), and green beams (G). By interposing a predetermined position of the magnet assembly, a pair of four-pole magnet ring for improving the OCV and a pair of six-pole magnet ring for improving the CCV in one artificial operation of the R, B, G Induces the beam and makes two spacers one spacer to improve the fabrication assembly quality and at the same time minimize the manufacturing cost, thereby improving productivity Due to this, not only to improve the economics of the overall cathode ray tube convergence, but also to provide a magnet assembly for convergence to improve fine tuning for maximizing efficiency.

1 is a configuration diagram showing that the convergence is generally installed in the cathode ray tube,

2 is a conceptual diagram showing a state in which an electron beam is focused on a mechanical center by a general adjustment;

3 is a schematic diagram showing displacement of an electron beam via a conventional magnet ring;

4 is a side view showing a convergence according to the present invention;

5A is a state diagram illustrating a dispersion degree of an electron beam according to the present invention;

5B is a state diagram illustrating a dispersion degree of an electron beam according to the present invention;

5C is a state diagram illustrating a dispersion degree of an electron beam according to the present invention;

5D is a state diagram illustrating a dispersion degree of an electron beam according to the present invention;

6 is a characteristic curve graph represented by the present invention.

<Explanation of symbols for the main parts of the drawings>

10: A pair of P-pole magnets 20: A pair of 4-pole magnets

30: A pair of 6-pole magnet ring 40: Space

50 holder CRT cathode ray tube

PCM: Convergence DY: Deflection Yoke

In order to achieve the above object, it will be described in detail with reference to the accompanying drawings which is a preferred embodiment of the present invention.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

The following terms are terms set in consideration of functions in the present invention, which may vary depending on the intention or custom of the producer, and the definitions should be made based on the contents throughout the present specification.

First, the present invention is shown in Figures 4 and 6, Figure 4 is a side view showing the convergence according to the present invention, Figures 5a to 5d is a state diagram for explaining the dispersion of the electron beam according to the present invention 6 shows a characteristic curve graph shown by the present invention.

That is, the present invention is interposed between the three magnets (10, 20, 30) of the three poles P-, 4-pole, 6-pole to form a magnetic pole in two pairs and each magnet ring to block the rotation interference of the magnet ring In the convergence of the non-magnetic holder 50 of the spacer 40 to be fixed sequentially, one side side beam (R beam, B beam) and the center of the R, G, B beam when the magnetic field of the magnet ring in the minimum magnetic state By interposing the beam (G-beam) and the spacer magnetized with a separate two or more asymmetric even poles that can adjust the CCV and OCV at the same time through a predetermined position of the magnet assembly.

In addition, the displacement direction of the CCV and the OCV by the spacer magnetized into the asymmetric even-numbered pole of the two or more poles is the synthesis (vector) direction of the upper right (+ direction) and the lower left (-direction) with respect to the center beam (G beam). Is made to adjust.

Position angle between the A pole and the D pole among two or more asymmetric even poles of the spacer ( ) Is greater than 20 ° and less than 150 ° (20 ° ≤ ≤ 150 °), the position angle beta between the A and B poles is 30 ° or more and 90 ° or less (30 ° ≤β≤90 °), and the position angle θ between the B and C poles is 20 degrees or more and 150 degrees or less (20 degrees <= <= 150 degrees).

On the other hand, the polarity (A, B, C, D) of the two or more asymmetric even poles magnetized in the spacer is limited to the fixed state to the S pole and the N pole, so as not to magnetize and the S pole and The position and direction of the N pole are deformed and magnetized.

The magnetic flux density amount (GAUSS amount) represented by the spacer 40 magnetized by the asymmetric even-numbered pole of the two or more poles is a range of the maximum value of the magnetic flux density amount at least according to the characteristics of the spacer 40 based on the maximum value ( t) is more than 5% (t ≧ 5%).

The present invention described above may be variously modified and may take various forms in the magnetic pole magnetization of the spacer.

It is to be understood, however, that the present invention is not limited to the specific forms referred to in the above description, but rather includes all modifications, equivalents and substitutions within the spirit and scope of the invention as defined by the appended claims. It should be understood to do.

The operation and operation relationship of the present invention configured as described above will be described.

First, the assembly of the present invention is fixed to the non-magnetic holder 50 by inserting three sets of magnet rings (10, 20, 30) of P-poles, 4-poles, and 6-poles which form magnetic poles in pairs one by one. In this case, the spacer 40 magnetized to an asymmetrical even pole of two or more poles is installed at a predetermined position in the magnet assembly.

That is, the spacer 40 may be installed between the third set of magnet rings 10, 20, and 30 of the P-pole, 4-pole, and 6-pole to improve the efficiency of fine adjustment, and the magnet is the P-pole. It may be installed at the rear end of the ring 10, and may also be installed at the front end of the six-pole magnet ring 30.

Convergence (PCM) in the state where the assembly is completed in the holder 50 is fitted to the neck portion at the rear end of the cathode ray tube (CRT).

In this case, when the magnets 10, 20, and 30 are in the minimum magnetic field state by adjusting the spacers 40 magnetized to two or more asymmetric even-numbered poles interposed in a predetermined position of the magnet assembly, R, G, The CCV and OCV are simultaneously adjusted by inducing displacement of one side beam (R beam, B beam) and the center beam (G beam) among the B beams, and the displacement direction of the CCV and OCV is based on the center beam (G beam). Adjustment is made in the combined (vector) direction of the upper right (+ direction) and the lower left (− direction) (see FIGS. 5A-5D).

For example, when the side beams (R beam, B beam) are to be shifted to 1.0 mm by OCV adjustment and to 0.5 mm by CCV adjustment, conventionally, by adjusting using 4 poles and 6 poles, Due to the difficulty in making accurate adjustments and the hassle of making the adjustments twice, the present invention using the spacers 40 magnetized with even-numbered poles having two or more poles is the same as that of the conventional ones. The displacements of the OCV and CCV are made in the synthesis direction diagonally so as to reach the same position.

At this time, the position angle between the A pole and the D pole of the two or more asymmetric even poles of the spacer ( ) Is greater than 20 ° and less than 150 ° (20 ° ≤ ≤ 150 °), the position angle beta between the A and B poles is 30 ° or more and 90 ° or less (30 ° ≤β≤90 °), and the position angle θ between the B and C poles is It is preferable to make it 20 degrees or more and 150 degrees or less (20 degrees <= (theta) <= 150 degrees) (refer FIG. 4).

This is achieved by modifying and modifying the magnet in order to improve the fine tuning of the OCV and CCV.

On the other hand, according to the characteristic curve shown in Figure 6, the magnetic flux density amount (GAUSS amount) represented by the spacer 40 magnetized with an asymmetric even pole of two or more poles is represented by the maximum value of +636.29, -636.29 As can be seen, at least 5% (t ≧ 5%) of the range t of the maximum value of the magnetic flux density amount may be displayed based on the maximum value according to the characteristics of the spacer 40.

The cathode ray tube convergence of the present invention is very useful for ITC work on an error-free tube in which the distance difference between each beam, that is, the OCV and CCV, is relatively slightly off from the reference value, resulting in difficulty of static focusing.

As a result, the error-free tube in the state of increased OCV and CCV is generally the connection error is large, so that the adjustment range is increased during the ITC operation to facilitate the static concentrating operation.

As described in detail above, the present invention provides an electron beam of a cathode ray tube (CRT) having a very small focusing error in adjusting static focusing with each magnet ring pair of cathode ray tube convergence installed in the neck portion of an inline type color picture tube (CPT). Separate two-pole or more asymmetrical to induce one side beam and two side beams among red beam (R), blue beam (B), and green beam (G) to adjust OCV and CCV simultaneously to artificially disperse By interposing an evenly magnetized spacer in a predetermined position of the magnet assembly, a pair of four-pole magnet rings for improving the OCV and a pair of six-pole magnet rings for improving the CCV are artificially operated in one operation. It has the effect of inducing the R, B, G beams, and excellent effect of fabrication assembling by making two spacers as one spacer, Minimizing the cost and an effect of saengsangseong improved, whereby it is obvious to be a very useful invention that can achieve multiple effects simultaneously, such that efficiency is maximized not only improves the economy of cathode-ray tubes convergence.

Claims (5)

P-poles, 4-poles, and 6-poles of the third set of magnet rings 10, 20, and 30, which form magnetic poles in pairs, and a spacer 40 interposed between the magnet rings so as to block the rotational interference of the magnet rings. In the convergence fixed in the holder 50 of the non-magnetic material in sequence, Separate two poles that can adjust CCV and OCV simultaneously by inducing displacement of one side beam (R beam, B beam) and center beam (G beam) among R, G, and B beams in the minimum magnetic field of each magnet ring. A magnet assembly for convergence with a magnet having an asymmetrical polarity, characterized in that it is formed by interposing a spacer magnetized by the above-mentioned asymmetric even-pole at a predetermined position of the magnet assembly. The method of claim 1, The displacement direction of the CCV and the OCV by the spacer magnetized by the bipolar asymmetric even-pole is adjusted in the combination (vector) direction of the upper (+) direction and the lower (-) direction with respect to the center beam (G beam). A magnet assembly for convergence formed with a magnet of asymmetric polarity, characterized in that consisting of. The method of claim 1, Position angle between the A pole and the D pole among two or more asymmetric even poles of the spacer ( ) Is greater than 20 ° and less than 150 ° (20 ° ≤ ≤ 150 °), the position angle beta between the A and B poles is 30 ° or more and 90 ° or less (30 ° ≤β≤90 °), and the position angle θ between the B and C poles is A magnet assembly for convergence with a magnet having an asymmetric polarity, characterized in that it is 20 ° or more and 150 ° or less (20 ° ≦ θ ≦ 150 °). The method of claim 1, The polarity (A, B, C, D) of two or more asymmetric even-poles magnetized in the spacer is limited to the fixed state of the S-pole and the N-pole and is not magnetized, and according to the efficiency of fine adjustment, the S-pole and the N-pole Magnet assembly for convergence formed with a magnet of an asymmetric polarity, characterized in that the magnetization is made so that the position and direction of the magnet. The method of claim 1, The magnetic flux density amount (GAUSS amount) represented by the spacer 40 magnetized by the asymmetric even-numbered pole of the two or more poles is a range of the maximum value of the magnetic flux density amount at least according to the characteristics of the spacer 40 based on the maximum value ( A magnet assembly for convergence with a magnet of asymmetrical polarity, characterized in that t) is formed at least 5% (t ≧ 5%).