KR20030073167A - Beam index type cathode ray tube having means of compensating geomagnetism - Google Patents

Abstract

PURPOSE: A beam index type cathode ray tube is provided to prevent a mis-match of the split screen of the cathode ray tube by minimizing influences of terrestrial magnetic field on the electron beam. CONSTITUTION: A beam index type cathode ray tube comprises a face panel(12) having a screen portion with an inner surface on which a phosphor screen is formed, and a skirt portion formed by bending, in a rearward direction, the circumference of the screen portion; a funnel coupled to the rear of the face panel, and which has one or more necks; electron guns mounted in each of the necks, and which scans electron beams to the area corresponding to the phosphor screen in accordance with the scanning direction; a plurality of deflection yokes mounted on the outer surface of the funnel, and which deflect electron beams emitted from the electron guns; index phosphors arranged on a black matrix; an optical detector mounted on the outer surface of the funnel, and which detects index signals generated from the index phosphors; a first coil unit(46) wound on the skirt portion along the outer surface of the face panel; second coil units(42a,42b) wound on the outer surface of the longer side skirt portion of the face panel; third coil units(44a,44b) wound on the outer surface of the shorter side skirt portion of the face panel; a terrestrial magnetic field sensor(52) for sensing the direction and intensity of the terrestrial magnetic field affecting the cathode ray tube; and a terrestrial magnetic field correction unit(50) connected to the first, second and third coil units and the terrestrial magnetic field sensor, and which generates a correcting magnetic field having an intensity similar to the intensity of the terrestrial magnetic field sensed by the terrestrial magnetic field sensor and a direction opposite from the direction of the terrestrial magnetic field.

Description

Beam index type cathode ray tube with geomagnetic field correction means {BEAM INDEX TYPE CATHODE RAY TUBE HAVING MEANS OF COMPENSATING GEOMAGNETISM}

The present invention relates to a cathode ray tube, and more particularly, a so-called multi-neck beam index type having two or more necks for one face panel while color separating an electron beam using an index signal. It relates to a cathode ray tube.

The beam index type cathode ray tube, which is a kind of cathode ray tube, is composed of a face panel, a funnel, and a neck tube like a conventional cathode ray tube, while the neck is equipped with an electron gun that emits an electron beam, Index phosphors are separately formed together with a fluorescent screen consisting of R), green (G), and blue (B) phosphors, and an outer side of the funnel is equipped with a deflector and a photo detector for sensing index light.

The beam index type cathode ray tube having such a configuration is designed to compensate for the problems of the general cathode ray tube, and detects an index signal excited by an electron beam emitted from an electron gun and synchronizes it with a color signal so that the electron beam always reaches a desired position. Thus, by emitting the corresponding phosphor, a predetermined image can be realized.

The advantage of the beam index type cathode ray tube is that there is no fear of mis-landing of the electron beam due to the shadowing phenomenon of the shadow mask, since it does not employ the shadow mask, which is a color sorting means, and only one electron gun is used to implement a color image. It is also possible to prevent misconvergence due to misalignment of R, G, and B electron beams.

On the other hand, the multi-neck beam index type cathode ray tube is usually composed of one panel and a funnel having two or more necks, and the divided screen corresponding to each neck is driven by applying the above-described method and These split screens are joined on the basis of the boundary to complete one full screen.

However, even if the screen bonding is perfectly realized at the boundary of each divided screen, if the divided screens move left and right or up and down under the influence of the geomagnetic field, screen mismatch occurs.

On the other hand, the earth's magnetic field on the earth can be divided into a horizontal geomagnetic field (B _h ) and a vertical geomagnetic field (B _v ).

Here, the horizontal geomagnetic field (B _h ) is a geomagnetic field that is formed from the south pole (S pole) toward the north pole (N pole) and is always positive (+) and becomes the maximum at the equator, and the vertical geomagnetic field (B _v ) is aerial. The geomagnetic field formed from the ground toward the ground is positive (+), and the geomagnetic field directed from the ground toward the air is negative (-). In other words, the vertical geomagnetic field (B _v ) is based on the equator (B _v = 0) and the northern hemisphere is formed in the positive (+) direction and becomes the maximum positive value in the north pole, and the southern hemisphere is formed in the minus (-) direction and It will be the maximum negative value.

In order to consider the effect of the geomagnetic field formed in this way on the cathode ray tube, the components of the geomagnetic field are divided, as shown in FIG. 5, the vertical geomagnetic field B _v and the north-south horizontal geomagnetic field B _h1 and the east-west horizontal It can be divided into a geomagnetic field (B _h2 ), which affects the path of the electron beam by the Fleming's left-hand law according to the position and direction of the cathode ray tube is placed, and consequently causes the screen to move.

As a result, since the color switching is performed by indexing in the beam index type cathode ray tube, there is no problem such as the color purity deterioration due to the mislanding phenomenon of the electron beam generated in the conventional shadow mask type cathode ray tube. Since the user is installed and used in various positions and directions according to the actual user, the screen moves due to the influence of the geomagnetic field, and thus there is a problem in that the junctions of the divided screens are shifted from each other.

As a technique for joining divided screens in a multi-neck beam index type cathode ray tube, Japanese Patent Application Laid-Open No. 8-273555 uses two index stripes to determine the position of an electron beam scanning a fluorescent screen two-dimensionally. For example, a method capable of correcting the position of the electron beam or the timing of the image signal corresponding to the second index signal is provided. According to this method, the scanning raster of the electron beam scanning each region can be corrected in a straight line to bond the screen raster with the raster of the adjacent screen, but the image screen is displaced at the boundary between the left and right screens under the influence of the geomagnetic field. The problem is not solved.

The present invention was devised to solve the above problems, and its object is to provide a geomagnetic sensor and a geomagnetic field correction means to prevent misalignment of the split screen without regard to the position and direction of use of the cathode ray tube. It is to provide a beam index type cathode ray tube.

1 is a schematic diagram of a cathode ray tube having a geomagnetic field correction means according to the present invention.

2 is a perspective view of a cathode ray tube having a geomagnetic field correction means according to the present invention.

3 is a cross-sectional view of a cathode ray tube having a geomagnetic field correction means according to the present invention.

4A is a diagram illustrating a state where junctions of the divided screens are shifted before the geomagnetic field is corrected.

4B is a diagram illustrating a good bonding of the divided screens after correcting the geomagnetic field.

5 is a diagram schematically showing the components of the geomagnetic field that affects the cathode ray tube.

* Description of the symbols for the main parts of the drawings *

10: tube 12: face panel

14: neck 15: electron gun

16: Conn 18: Funnel

20: fluorescent screen 22: black matrix (BM)

24: R, G, B phosphor 25: aluminum thin film

26, 28: index phosphor 32, 34: photo detector

42a, 42b: second coil portion 44a, 44b: third coil portion

46: first coil unit 50: geomagnetic field correction unit

52: geomagnetic sensor B _v : vertical geomagnetic field

B _h1 , B _h2 : horizontal geomagnetic field

In order to achieve the above object, according to the present invention, a fluorescent screen in which a plurality of red (R), green (G), and blue (B) phosphors are repeatedly arranged on an inner surface of a screen is interposed with a black matrix (BM). A face panel which is bent rearwardly around the portion to form a skirt portion; A funnel coupled to the back panel and having at least one neck; An electron gun respectively mounted in the neck and separately scanning an electron beam according to each scanning direction in a corresponding region of the fluorescent screen; A plurality of deflection yokes corresponding to the electron guns for deflecting the electron beams which are provided on the outer periphery of the funnel and are scanned from the respective electron guns to the area of the split fluorescent screen; Index phosphors arranged alternately on the black matrix at predetermined intervals; A photo detector provided on the outer surface of the funnel corresponding to each area of the fluorescent screen and detecting an index signal generated from the index phosphor; A first coil part wound around the skirt portion several times along an outer circumference of the face panel; A second coil part wound around the axis perpendicular to the outer side of the long side skirt part of the face panel; A third coil part wound around a shaft perpendicular to an outer surface of the short side skirt part of the face panel; A geomagnetic field sensor for sensing the direction and intensity of the geomagnetic field on the cathode ray tube; And an earth magnetic field correction unit connected to the first, second and third coil units, and the earth magnetic field sensor, to generate a corrected magnet having a strength similar to that of the earth magnetic field detected by the earth magnetic field sensor, and having opposite directions. It provides a beam index type cathode ray tube comprising a.

Here, the second coil portion and the third coil portion are preferably formed to be symmetrical to each other a pair of long side and a pair of short side.

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

1 is a schematic view of a cathode ray tube with a geomagnetic field correction means according to the present invention, FIG. 2 is a perspective view of a cathode ray tube with a geomagnetic field correction means according to the present invention, and FIG. 3 is a geomagnetic field correction according to the present invention. It is a cross-sectional view of a cathode ray tube provided with a means.

As shown, the cathode ray tube according to an embodiment of the present invention is a funnel 18 having two necks 14 and two cone portions 16 behind the face panel 12 are integrally coupled to the cathode ray tube. The tube 10 is configured, and the inside of the tube 10 maintains a high vacuum state of about 10 ⁻⁷ to 10 ⁻¹⁰ Torr so as to allow electrons to move freely.

In addition, the set circuit portion of the cathode ray tube (not shown) synthesizes an index signal obtained by the action of the electron beam generated inside the tube 10, and synchronizes the synthesized index signal with the R, G, and B color signals to determine the current density of each electron beam. An index signal processing apparatus for controlling the degree of deflection is provided.

Furthermore, a fluorescent screen 20 made up of a black matrix 22 and a plurality of R, G, and B phosphors 24 repeatedly arranged between the black matrix 12 on an inner surface of the face of the face panel 12. The aluminum thin film 25 is formed on the R, G, and B phosphors 24 and the black matrix 22.

In particular, the index phosphors 26 and 28 for generating an index signal are formed on the aluminum thin film 25, and each has a unique emission wavelength or emission energy corresponding to the position where the black matrix 22 is disposed. The first and second index phosphors 26 and 28 are alternately arranged one by one at regular intervals over the entire left and right screens, or one type in each of the left and right screens.

An electron gun 15 is mounted inside each neck 14 to emit a line of electron beam toward the fluorescent screen 20, while a deflection yoke 19 generates a deflection magnetic field on the outer circumferential surface of each cone portion 16. Is installed.

In addition, each neck 14 includes a first photodetector 32 corresponding to an emission wavelength or emission energy of the first index phosphor 26 and a second photodetector 34 corresponding to the second index phosphor 28. On the basis of)) is installed in pairs on the left and right or the corner of the outer surface of the funnel 18, respectively.

In this case, the first and second photodetectors 32 and 34 may use other kinds of selectively responding to a specific emission wavelength or emission energy, or an integrated type thereof may be used. In addition, a filter corresponding to the emission wavelength of each index phosphor may be attached to the first and second photodetectors 32 and 34.

As a result, the electron beams emitted from the respective electron guns 15 are deflected by the magnetic field generated by the deflection yoke 19 to scan the left and right regions of the fluorescent screen 20 individually, and each electron beam is left and right. From the beginning of the effective screen of the right area, the horizontal scanning is simultaneously performed toward the screen boundary.

In the electron beam scanning process, the first and second index phosphors 26 and 28 emit their respective index lights, and the first and second photodetectors 32 and 34 detect the corresponding index lights to detect the index light. When the output signal is supplied to each other, each electron beam is color-separated into the corresponding R, G, and B phosphors 24 through the control of the index signal processing apparatus.

On the other hand, the cathode ray tube according to the present invention, as shown in Figure 1, is provided with a geomagnetic field correction means.

The geomagnetic field correction means detects the coil units 42a, 42b, 44a, 44b, 46 that are installed outside the cathode ray tube to form a correction magnetic field, the geomagnetic field correction unit 50 that controls such coil units, and the geomagnetic field. It consists of a geomagnetic field sensor 52 that serves to transfer the information to the geomagnetic field correction unit 50.

The coil part should be able to form a correction magnet in the X, Y, and Z axis directions. Preferably, the first coil part 46, the second coil parts 42a, 42b, and the third coil part 44a, 44b) are formed to be perpendicular to each other.

That is, the first coil part 46 is formed by winding the coil several times along the outer circumference of the face panel 12 of the cathode ray tube, and the second coil parts 42a and 42b are formed of the face panel 12. The coil is formed several times around an axis perpendicular to the outer side of the long side skirt, and the third coils 44a and 44b are wound around the axis perpendicular to the outer side of the short side skirt of the face panel 12. Form by winding.

At this time, the number of coil turns of each of the first coil part 46, the second coil parts 42a and 42b, and the third coil parts 44a and 44b should be increased in proportion to the size of the cathode ray tube.

The second coil parts 42a and 42b are formed to be symmetrical with each other on a pair of long sides of the face panel 12, and the third coil parts 44a and 44b are a pair of the face panels 12. It is preferable to form the short sides of the symmetrical to each other.

In addition, the coils of the second and third coil parts 42a, 42b, 44a, and 44b are wound along the edges of the long and short sides of the face panel 12, respectively, to thereby face the face panel 12 of the cathode ray tube. ) A uniform correction field can be formed throughout.

As a means for fixing the coil portions 42a, 42b, 44a, 44b, 46 to the face panel 12, in the large cathode ray tube, a constant groove is provided in the wing portion of the explosion-proof band in a conventional large cathode ray tube. As in the case where the element coil hanger is installed to fix the element coil, a method of providing a constant groove in the wing portion of the explosion-proof band and attaching the mounting hanger to the groove can be employed.

The coil portion may be formed in the skirt portion of the face panel 12 as described above, but may also be formed in the tip portion of the deflection yoke 19. Here, the tip portion refers to the funnel between the skirt portion of the panel 12 and the deflection yoke 19.

On the other hand, the geomagnetic field correction unit 50 is connected to the coil units 42a, 42b, 44a, 44b, 46 to receive the current controlled in accordance with the geomagnetic field information detected from the geomagnetic field sensor 52 the coil unit 42a. And 42b, 44a, 44b, and 46 to generate a correction magnetic field.

The geomagnetic field correction unit 50 is composed of a controller, a memory, a power supply and an interface in detail.

In addition, the geomagnetic field sensor 52 is installed in the main body of the television employing the cathode ray tube to sense the direction and intensity of the geomagnetic field applied to the cathode ray tube according to the position of the cathode ray tube of the present invention. Information about the geomagnetic field sensed by the geomagnetic field sensor 52 is transmitted to the controller of the geomagnetic field correction unit 50 to control the strength of the current flowing through the coil to form a correction magnet that can cancel the geomagnetic field. do.

At this time, in accordance with the strength of the magnetic field to be formed to determine the strength of the current to be passed to each of the coil parts (42a, 42b, 44a, 44b, 46) by experiment in advance, and then to the geomagnetic field correction unit 50 By inputting into the memory, it is possible to correct in real time even if the television equipped with the cathode ray tube according to the present invention is placed in any position or direction.

When the influence of the geomagnetic field is reduced by using the geomagnetic field correction means of the cathode ray tube according to the present invention, as shown in Fig. 4b, the bonding state at the boundary surface of the split screen is good. That is, as shown in FIG. 4A, the vertical shift of the left and right split screens before the correction may be corrected as shown in FIG. 4B.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it is within the scope of the present invention.

As described above, the beam index type cathode ray tube according to the present invention minimizes the influence of the geomagnetic field on the electron beam scanned from the electron gun by generating a correction magnetic field capable of detecting and canceling the magnetic field affecting the cathode ray tube. Therefore, there is an effect that the junction part shift of the split screen of the multi-neck beam index type cathode ray tube can be prevented.

In addition, according to the detected geomagnetic field, the current to be applied to each coil unit is determined in advance and input into the memory, thereby real-time correction is possible even when the television or the like is placed in any position or direction.

Claims (4)

A fluorescent screen in which a plurality of red (R), green (G), and blue (B) phosphors are repeatedly arranged is formed on the inner surface of the screen portion, and the skirt portion is bent backward around the screen portion. Face panels; A funnel coupled to the back panel and having at least one neck; Electron guns respectively mounted in the neck and individually scanning electron beams in respective scanning directions in corresponding regions of the fluorescent screen; A plurality of deflection yokes corresponding to the electron guns for deflecting the electron beams which are provided on the outer periphery of the funnel and which are scanned from the respective electron guns to the area of the split fluorescent screen; Index phosphors alternately arranged at predetermined intervals on the black matrix; A photo detector provided on the outer side of the funnel corresponding to each area of the fluorescent screen and detecting an index signal generated from the index phosphor; A first coil part wound around the skirt portion several times along an outer circumference of the face panel; A second coil part wound around the axis perpendicular to the outer side of the long side skirt part of the face panel; A third coil part wound around the axis perpendicular to an outer surface of the short side skirt part of the face panel; A geomagnetic field sensor for sensing the direction and intensity of the geomagnetic field on the cathode ray tube; And A geomagnetic field correction unit connected to the first, second and third coil units and the geomagnetic field sensor, and configured to generate a correction magnetic field having an intensity similar to that of the geomagnetic field detected by the geomagnetic field sensor and opposite in direction. Beam index type cathode ray tube comprising a. The method of claim 1, The second coil portion is a beam index type cathode ray tube formed to be symmetrical to each other a pair of long sides. The method of claim 1, And the third coil part is formed to be symmetrical with each other on a pair of short side parts. The method of claim 1, The geomagnetic field correction unit is a beam index type cathode ray tube comprising a controller, a memory, a power supply and an interface.