KR100921798B1 - Holder of Purity Convergence Magnet - Google Patents

Abstract

PURPOSE: A magnet holder of the electron beam focusing apparatus is provided to fix the insertion fixation pin of the magnet holder from the cylindrical neck by adjusting the thickness of the insertion fixation pin of the magnet holder. CONSTITUTION: A magnet holder of the electron beam focusing apparatus includes a torus body(51) which has a plurality of downward jaws and a upward jaw(521); a plurality of support pins(52) to which the plurality of torus bodies; a reinforcing support(55) which is installed at the lower part of the torus body to reinforce the intensity of the torus body; an insertion fixation pin(53) which is inserted into the cut formed in the cylindrical neck of the deflecting yoke faces at the lower part of the torus body to reinforce the intensity of the insertion fixation pin.

Description

Magnet holder for electron beam focusing device {holder of Purity Convergence Magnet}

The present invention relates to a color cathode ray tube, and more particularly to a magnet holder of an electron beam focusing device provided on a cylindrical neck of a color cathode ray tube.

In general, glass cathode ray tubes (CRTs), which implement color images, are roughly divided into aperture, trio, and in-line methods. The cathode ray tube is focused on the electron beam focusing device (PCM: Purity Convergence Magnet) of the red (R), green (G), and blue (B) electron beams emitted from the electron gun installed inside the glass tube of the electron gun site. The focused electron beam is deflected by the horizontal and vertical magnetic fields generated in the deflection yoke (DY), and is horizontally and vertically scanned at the exact position of the phosphor screen through a shadow mask to display a color image.

The above-mentioned electron beam focusing device (PCM) and deflection yoke (DY) are fitted with a deflection yoke on the outer circumferential surface of the cylindrical neck of the color cathode ray tube (CRT) as shown in FIG. 1 of the Korean Utility Model No. 20-0189220 (inserted clamp). Clamps with tightening bolts are tightened and fixed on the cylindrical neck of the high deflection yoke, and an electron beam focusing device (PCM) is fitted behind the deflection yoke and is fixed by clamps with tightening bolts.

The electron beam focusing apparatus (PCM) includes a plurality of ring-shaped magnets including a rocker and a washer spring and spaced apart by spacers to form horizontal and vertical magnetic fields; A plurality of lower pins on which a plurality of ring magnets are fitted; And a magnet holder having a plurality of upper pins into which the cramps are fitted.

As such, each of the electron beam focusing device (PCM) and the deflection yoke (DY) is fixedly installed with a clamp having a tightening bolt. In particular, in the case of the electron beam focusing device (PCM), the cost of the clamp is high, so the clamp of the deflection yoke is reduced. As shown in FIGS. 1 and 2, the magnet holder 10 has a plurality of downward locking jaws to fix the deflection yoke and the electron beam focusing device (PCM) to the cylindrical neck of the color cathode ray tube (CRT). Circular ring body 11 is installed and the plurality of support pins are installed spaced apart from each other on the upper portion of the circular ring body and the upper locking jaw 121 is discontinuously installed on the top and a plurality of ring-shaped magnets 30 are installed ( 12), a plurality of insertion fixing pins 13 installed in the lower portion of the circular ring body, and a plurality of stoppers 14 for limiting the insertion depth of the insertion fixing pins, and the clamp 22 of the deflection yoke 20. Magnet on the cylindrical neck (21) on which A plurality of cutout grooves 23 into which the insertion fixing pin 13 of the holder 10 is inserted are formed at intervals in six directions of the "*" direction, that is, the "x" and "|" directions.

The stopper 14 of the magnet holder 10 restricts the insertion depth of the insertion fixing pin 13 inserted into the cutout groove 23, and the upper thickness surface A of the cylindrical neck 21 of the deflection yoke 20. ) To limit the insertion depth of the insertion fixing pin (13). The upper locking jaw 121 is discontinuously installed in a manner that is once installed on the upper ends of the plurality of support pins 12 and is not installed once, and thus the upper locking jaws 121 are installed to face each other.

However, since the distance between the plurality of cutout grooves 23 of the cylindrical neck 21 of the deflection yoke 20 is not constant for each deflection yoke for each manufacturer, the plurality of insertion pins 13 of the magnet holder 10, for example, an insertion In the case of four fixing pins, there is a problem in that a plurality of magnet holders for deflection yokes for each manufacturer have to be provided because they cannot be inserted in correspondence with each of the four cutout grooves 23 formed in the “×” direction.

In addition, since the thickness A of the cylindrical neck 21 of the deflection yoke 20 is not constant for each deflection yoke for each manufacturer, the thickness A of the cylindrical neck 21 of the deflection yoke 20 is shown in FIG. As shown, if the thickness is greater than the thickness of the insertion fixing pin 13 of the magnet holder 10, there is a gap (t) between the insertion fixing pin and the clamp, so even if tightened with the clamp 22, the insertion fixing pin 13 is When the magnet holder 10 is pulled by being in contact with the clamp 22, the magnet holder 10 is easily detached from the cylindrical neck 21 of the deflection yoke 20, and thus the magnet holder 10 cannot be fixed. When the thickness A of the cylindrical neck 22 is thinner than the thickness of the insertion pin 13 of the magnet holder 10, as shown in FIG. 3 (b), the insertion pin 13 is made of the deflection yoke ( Since the contact with the clamp 22 before the cylindrical neck 21 of 20), the insertion fixing pin 13 is pushed by the pressing force of the clamp and the glass material collar The cylindrical neck 30 of the cathode ray tube (CRT) is applied to the glass neck has a problem that the neck 40 cracks or breaks. Reference numeral 41 is a tape for protecting the cylindrical neck 40 made of glass.

It is an object of the present invention to solve the above-mentioned problems, so that the fixing pin of the magnet holder can be inserted into the cutout groove regardless of the manufacturer's deflection yoke, the thickness of the cylindrical neck of the deflection yoke and the fixing pin of the magnet holder The magnet holder can be fixed to the cylindrical neck of the deflection yoke by matching the thickness of the magnet holder or by thickening the insertion pin of the magnet holder to the thickness of the cylindrical neck of the deflection yoke so that the magnet holder does not deviate from the cylindrical neck of the deflection yoke. On the other hand, it is to provide a magnet holder of the electron beam focusing device so that the cylindrical neck of the glass color cathode ray tube (CRT) of the glass material on which the electron beam focusing device (PCM) is installed is not cracked or broken.

The object of the present invention described above is a plurality of support pins are provided with a circular ring body and a plurality of downward locking jaw is installed, spaced apart from each other on the upper portion of the circular ring body and the upper locking jaw is discontinuously installed at the top and a plurality of ring magnets are installed. A magnet holder of an electron beam focusing apparatus, comprising: a plurality of reinforcing bars installed on a lower portion of the circular ring body to face each other to reinforce the strength of the circular ring body; The lower part of the circular ring body further includes an insertion fixing pin which is installed to face the two inserted into the notch groove formed in the cylindrical neck of the deflection yoke, reinforcing the strength of the insertion fixing pin on one side or both sides of each of the two insertion fixing pins It is achieved by a magnet holder of the electron beam focusing device which integrally forms a reinforcing bar combined stopper for limiting the insertion depth of the insertion fixing pin, and each of the two insertion fixing pins has a groove formed on the outer surface which is in contact with the clamp.

In the magnet holder of the electron beam focusing apparatus of the present invention, the thickness of the groove-inserted fixing pin is equal to or thicker than the thickness of the cylindrical neck of the deflection yoke.

In the magnet holder of the electron beam focusing apparatus of the present invention, the grooves of the insertion pins are grooves in which the inner wall surfaces of the both side wall walls formed by the grooves are protruded, and the inner wall surfaces of the both side wall walls protrude from the insertion pins. It is characterized in that the thickness is equal to or thicker than the thickness of the cylindrical neck of the deflection yoke.

In the magnet holder of the electron beam focusing apparatus of the present invention, the groove of the insertion pin is characterized in that a plurality of holes are formed at a single hole or at intervals.

In the magnet holder of the electron beam focusing apparatus of the present invention, the thickness of both side finger walls formed by the groove of the insertion pin is characterized in that one side is thinner than the other side or the same side and the other side.

In the magnet holder of the electron beam focusing apparatus of the present invention, the thickness of one side and the other side finger wall is 0.6 to 1.0 mm.

In the magnet holder of the electron beam focusing apparatus of the present invention, the outer surface of the other finger wall contacting the cylindrical neck of the deflection yoke is cut out so as to have the same thickness of the finger wall on the one side and the other side.

The fixing pin of the magnet holder can be inserted into the cutout groove regardless of the manufacturer's deflection yoke by the insert fixing pin of the present invention as described above, and the magnet holder is not detached from the cylindrical neck of the deflection yoke. The cylindrical neck may be fixed to the cylindrical neck, and the cylindrical neck of the glass color cathode ray tube (CRT) in which the electron beam focusing device (PCM) is installed is not cracked or broken.

Hereinafter, specific technical configurations and operations of the present invention will be described in detail with reference to the accompanying drawings.

Figure 4 is a perspective view showing a magnet holder of the present invention, Figure 5 is a perspective view showing a deflection yoke equipped with the magnet holder of the present invention, Figure 6 is a fixing pin of the magnet holder of the present invention is mounted to the deflection yoke (A) is a view showing a state in which an insertion fixing pin thicker than the thickness of the deflection yoke is mounted on the deflection yoke to receive the clamping force, and (b) is (a). When the fixing pin is pressed by the clamp in the state of the drawing is a view showing a state in which the protruding inner wall surfaces of the both side wall wall is crushed into the groove or in the other direction to absorb the clamping force of the clamp.

In the technical construction of the present invention, the same technical construction as in the prior art uses the same reference numeral.

The magnet holder 50 of the electron beam focusing apparatus (PCM) of the present invention has a circular ring body 51 in which a plurality of downward locking jaws 511 are installed, and is spaced apart from each other on an upper portion of the circular ring body and has an upper locking jaw at the top ( 521 is discontinuously installed and comprises a plurality of support pins 52 are provided with a plurality of ring-shaped magnets (30).

Looking at the specific features of the magnet holder 50 of the electron beam focusing device (PCM) of the present invention configured as described above, the circular ring body 51 to face each other four reinforcing rods 54 to reinforce the strength of the circular ring body 51 ) Is installed in the lower part of the circular ring body 51 so as to face each other, the two insertion fixing pins (53) inserted into the notch groove 23 formed in the cylindrical neck of the deflection yoke, On one side or both sides of each of the fixing pins to reinforce the strength of the insertion fixing pin while forming a reinforcing bar combined stopper 55 to limit the insertion depth of the insertion fixing pin, and each of the two insertion fixing pins abut the clamp 22 The groove 531 is formed on the outer surface.

Figure 4 shows that the lower locking jaw is installed on one side of the insertion fixing pin, but the reinforcing bar combined stopper 55 is installed only on the other side, but adjusting the position of the lower locking jaw to insert the fixing bar combined stopper (55) It is also preferable to reinforce the strength of the insertion pin by installing on both sides of the.

Among the characteristics of the magnet holder 50, two insertion fixing pins 53 are installed in a straight line to face each other, so that the distance between the six notched grooves of the cylindrical neck of the deflection yoke is constant for each deflection yoke by the manufacturer. If not, two insertion fixing pins are formed in a straight line so that the six notched grooves 23 are in the "*" direction, i.e., in the six directions of "x" and "|", regardless of the distance between the six notched grooves 23. The conventional problem is solved because it is necessary to select and insert only two cutout grooves on one straight line among three straight lines.

In addition, the magnet holder is fixed in the cylindrical neck 21 of the deflection yoke 20 because the magnet holder is clamped by clamping after the magnet holder is balanced. It will not break away.

In addition, the insertion fixing pin 53 is a protruding elongate shape, so that the magnet holder does not turn in the direction of the rocker rotation when the locker is turned during the handling of the magnet holder 50 or after installing a plurality of ring-shaped magnets on the plurality of support pins. It can be broken, so that one side or both sides of the reinforcing bar combined stopper 55 is integrally formed, which stops the insertion fixing pin so that the insertion fixing pin does not break during the handling of the magnet holder 50 or when the magnet holder is rotated. In addition to acting as a reinforcement, it also plays a role of limiting the insertion depth of the insertion pin that is inserted into the cutout groove.

And the lower portion of the circular ring body four reinforcing rods 54 are installed facing each other to reinforce the strength of the circular ring body. When the two insertion fixing pins 53 are completely inserted into the two cutout grooves 23, the four reinforcing bars 54 are positioned above the four cutout grooves.

The thickness of the insertion pin (53) formed with the groove 531 of the present invention is equal to or thicker than the thickness of the cylindrical neck 21 of the deflection yoke (20), the groove 531 of the insertion pin (53) is The inner wall surfaces of both side wall walls 532 and 533 formed by the grooves are protruding grooves, and the shape of the fixing pin and the grooves may be parallelograms as shown in FIG. 6, and the grooves may be rectangular in addition to the parallelograms. It may be in various shapes such as semicircular.

And the thickness of the both sides of the tungsten wall 532, 533 formed by the groove of the insertion pin is thinner than the other side or the same side and the other side, the thickness of the one side and the other side is 0.6 ~ 1.0mm It is preferable. The reason is that if it is 0.6 mm or less, the finger wall may be broken, and if it is 1.0 mm or more, the finger wall may not be burnt.

For example, the thicknesses of both side finger walls may be 0.7 mm, or the thickness of the other side finger walls may be 0.7-1.0 mm thicker than 0.6 mm, which is the thickness of one side finger wall.

If the one side and the other side are the same, the thickness of the tungsten wall on both sides of the groove 531 may be the same, but as shown in FIG. 6C, the cylindrical neck 21 of the deflection yoke 20 of the other tungsten wall 533 is the same. It is also possible to cut out the outer part which abuts and to make it the same.

Accordingly, when the insertion fixing pin 53 of the magnet holder 50 inserted into the cylindrical neck 21 of the deflection yoke 20 is tightened by the clamp 22 to prevent separation, the deflection yoke 20 is applied. Since the inner wall surfaces of the both sides of the fingerboard wall are thicker than the thickness of the cylindrical neck 21 of, it is naturally in contact with the clamp, and the thickness of the cylindrical necks 21 of the deflection yoke 20 and the inner walls of the sides of the fingerboard wall protrude. As they coincide, both clamping walls are forced by the clamping force of the clamp.

When the insert fixing pin and the groove of FIG. 6 have a parallelogram shape, the force is applied in the direction of the arrow in (a). The thin one side finger wall 532 receives the force in the inner direction of the groove, but the other side is thick. 533 is subjected to a force in the inner direction or the other direction of the groove so that the inner wall surface of the protruding both side wall 532, 533 of the groove 531 is crushed or thick as shown in Figure 6 (b) The clamping force of the clamp is applied to the cylindrical neck 40 of the glass cathode ray tube (CRT) because the other side of the tank wall 533 is crushed in the other direction, so that the clamping force of the clamp is not applied. Glass-shaped cylindrical neck 40 is not cracked or broken.

In addition, since the insertion fixing pin 53 of the magnet holder 50 contacts the clamp 22 and is tightened by the clamp, the insertion fixing pin of the magnet holder is fixed by the clamp in the notched groove of the cylindrical neck of the deflection yoke so as not to be separated. do.

The reason for equal thickness of both side walls is that the clamping force of the clamp is balanced and distorted, so that the clamping force of the clamp is absorbed the same, so it is more efficient to crack or break the cylindrical neck 40 of glass material. It can be prevented.

The reason why the thickness of the other tanger wall 533 is thicker than the one of the tangerine wall 532 is that the bottom edge 535 of the inner wall surface of the other tangerine wall is distorted in the other direction as shown in FIG. In other words, the crack may occur at the bottom edge of the other side wall of the groove is considered.

In addition, when a plurality of holes 534 are formed in the groove 531 of the insertion fixing pin 53, which is long in the shape of an oval or have a certain interval, the clamping walls may be pressed by both clamping walls. Since the clamping force of the clamp is better absorbed more efficiently, it may be a preferred embodiment to form a hole.

The magnet holder of the present invention has the effect as described above, the assembly line of the production line holding the magnet holder 50 by hand and the linear insertion fixing pins 53 facing each other in the cylindrical shape of the deflection yoke 20 When one of the six notched grooves 23 of the neck 21 is selected and inserted into one of the two notched grooves 23 in a straight line, the insertion fixing pin 53 is inserted into the notched grooves, and then one or both reinforcing bars are combined. Since the stopper 55 is caught on the upper surface (thickness surface A) of the cylindrical neck 21 of the deflection yoke 20, the insertion fixing pin 53 stops the insertion. At this time, the four reinforcing table 54 is located on the top of the remaining four notch groove (23).

Subsequently, when the clamping pin 53 and the cylindrical neck 21 of the deflection yoke 20 are tightened with the clamp 22 as shown in FIG. 6, both side walls of the insert fixing pin are crushed as described above. Since the clamp 22 holds the insertion fixing pin in close contact with the cylindrical neck 40 of the color cathode ray tube (CRT) made of glass, the magnet holder 50 is a notch groove of the cylindrical neck 21 of the deflection yoke 20. While not being separated at 23, the glass-shaped cylindrical neck 40 is not damaged such as cracking or breaking.

1 is an exploded perspective view showing a magnet holder in a conventional deflection yoke.

Figure 2 is an assembled perspective view showing a deflection yoke equipped with a conventional magnet holder.

Figure 3 (a) and (b) is a partial cross-sectional plan view showing an operation state is mounted to the deflection yoke, the insertion pin of the conventional magnet holder.

Figure 4 is a perspective view of the magnet holder of the present invention.

5 is a perspective view showing a deflection yoke equipped with a magnet holder of the present invention.

Figure 6 (a) and (b) is a partial cross-sectional plan view showing an action state is mounted to the deflection yoke the insertion pin of the magnet holder of the present invention.

** Explanation of symbols for main parts of drawings **

10,50: magnet holder 11,51: circular ring body

111,511: Lower locking jaw 12,52: Support pin

121,521: Upper locking jaw 13,53: Insertion fixing pin

531: Home 532,533: Tanji Wall

54: reinforcing bar 55: reinforcing bar combined stopper

Claims (7)

A magnet of an electron beam focusing apparatus including a circular ring body having a plurality of downward locking jaws, and a plurality of support pins spaced apart from each other on an upper portion of the circular ring body and discontinuously installed with an upper locking jaw at an upper end thereof, and having a plurality of ring-shaped magnets. In the holder, A plurality of reinforcing bars installed at a lower portion of the circular ring body to face each other to reinforce the strength of the circular ring body; The lower part of the circular ring body further includes an insertion fixing pin which is installed to face the two inserted into the notch groove formed in the cylindrical neck of the deflection yoke, reinforcing the strength of the insertion fixing pin on one side or both sides of each of the two insertion fixing pins The magnet holder of the electron beam focusing apparatus, characterized in that the stopper combined stopper for limiting the insertion depth of the insertion fixing pin integrally formed, and each of the two insertion fixing pins formed a groove on the outer surface in contact with the clamp. The magnet holder of an electron beam focusing apparatus according to claim 1, wherein the thickness of the grooved insertion pin is equal to or thicker than the thickness of the cylindrical neck of the deflection yoke. The groove of the insert fixing pin is a groove in which the inner wall surfaces of both side finger walls formed by the groove protrude, and the inner wall surfaces of the both side finger walls protrude so that the thickness of the insert fixing pin is a cylindrical neck of the deflection yoke. Magnet holder of the electron beam focusing apparatus, characterized in that the thickness or the thickness of the. The magnet holder of an electron beam focusing apparatus according to any one of claims 1 to 3, wherein a plurality of holes are formed in a groove of the insertion pin. The magnet holder of an electron beam focusing device according to any one of claims 1 to 3, wherein the thickness of both side finger walls formed by the groove of the insertion pin is thinner than one side or the same as the other side. The magnet holder of an electron beam focusing apparatus according to claim 5, wherein the thickness of one side and the other side of the finger wall is 0.6 to 1.0 mm. The magnet holder of the electron beam focusing apparatus according to claim 5, wherein the outer surface of the other fingerboard wall which is in contact with the cylindrical neck of the deflection yoke is cut out so as to have the same thickness of the fingerboard wall of the one side and the other side.

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