KR200217866Y1 - Apparatus for settling a cathod-ray tube making use of artificial magnetic field - Google Patents

Abstract

The present invention relates to a CRT control device using an artificial earth magnetic field, and more particularly to a CRT control device using an artificial earth magnetic field to suppress the magnetic interference between the room and the room forming the artificial earth magnetic field.

This invention has a plurality of magnetic field generating means which is installed in the front, rear, up and down, left and right directions of the CRT to generate a magnetic field to form a plurality of geomagnetic field; Magnetic field damping means provided on both sides of the magnetic field generating means between the geomagnetic field room and the geomagnetic field room to attenuate the magnetic field generated in the geomagnetic field room; Power supply means for applying power to the magnetic field generating means and the magnetic field attenuation means; It is characterized in that it comprises a magnetic field control means connected to the power supply means, the magnetic field generating means and the magnetic field attenuation means to control the magnetic field formation in the geomagnetic field room.

Description

Apparatus for settling a cathod-ray tube making use of artificial magnetic field

The present invention relates to a CRT control device using an artificial earth magnetic field, and more particularly to a CRT control device using an artificial earth magnetic field to suppress the magnetic interference between the room and the room forming the artificial earth magnetic field.

FIG. 1 is a schematic diagram showing the internal structure of a typical CRT tube. In the CRT tube 1, a screen is displayed by emitting a phosphor in which an electron beam emitted from an electron gun 2 is applied to a fluorescent surface 3.

Such CRT causes refraction while the electron beam emitted from the electron gun 2 reaches the fluorescent surface 3, and the refraction varies according to the intensity and direction of the magnetic field.

That is, in FIG. 1, when the magnetic field is '0', if the phase is adjusted to form 'C' point, when the magnetic field is changed, the CRT (1) appears as if the image is moved to the 'A' point or 'B' point. Is affected by the Earth's magnetic field and causes various characteristic changes on the screen.

Therefore, the picture of the CRT is that as the global magnetic field value of each region of the world changes, a screen abnormality may occur in another region where the magnetic field value is different even though a perfect normal screen appears in one region.

In order to adjust the picture abnormality of the CRT, the CRT controller using artificial earth magnetic field is used to adjust the CRT of the CRT which may occur according to the magnetic field value of a specific region.

Figure 2 is a block diagram showing the artificial geomagnetic field CRT adjustment apparatus of the prior art, Figure 3 is a block diagram showing the artificial geomagnetic field system.

Conventional artificial earth magnetic field tube adjustment device is a conveyor 11 for transporting the tube 1, as shown in Figure 2, and is positioned around the conveyor 11, the magnetic field in the front, rear, up and down, left and right directions of the tube (1) A magnetic field generating coil 20 which generates and forms a geomagnetic field R, a power supply 13 for applying power to the magnetic field generating coil 20, the power supply 13 and a magnetic field generating coil 20 It is composed of a magnetic field controller 15 is connected between the) to control the magnetic field formation.

In addition, as shown in FIG. 3, the magnetic field controller 15 includes magnetic field memories 16 and 17 for storing the magnitude of the magnetic field and current values, and a Gaussian setting box 18 for setting the magnitude of the magnetic field. The magnetic field display panel 19 showing the magnetic field generated from the geomagnetic field room R and the magnetic field measurement sensor 14a and the Gaussian meter 14b for measuring the magnetic field in the geomagnetic field R are provided. Each is connected.

The magnetic field generating coil 20 has a pair of horizontal (X) magnetic coils 21a and 21b for forming a magnetic field on the front and rear surfaces of the CRT as shown in FIG. 4, and as long as a magnetic field is formed on the top and bottom of the CRT. A pair of vertical (Y) magnetic field coils 22a and 22b and left and right surface Z magnetic field coils 23a and 23b forming a magnetic field on the left and right sides of the CRT.

The magnetic field generating coil 20 will be described with reference to FIGS. 5 and 6 by taking the left and right magnetic field coils 23a and 23b as an example. In order to generate a uniform magnetic field in the geomagnetic field room R, two parallel lines are formed. A coil is wound around the copper wire 25 several hundred times to form a coil, and when a current is applied to both coils, a uniform magnetic field distribution is formed at the center portion. As a result, by controlling the supply amount and the winding ratio of the current to such a coil it is possible to obtain a geomagnetic field for each region.

The artificial geomagnetic CRT controller as described above reads the currents for all the necessary magnetic field values at intervals of 0.1 G from -0.60 to +0.60 G for each combination of the X, Y, and Z magnetic fields in the magnetic field controller 15. The current pair for the magnetic field is stored in the first magnetic field memory 16.

Then, the global magnetic field values on the earth using the CRT 1 are stored in the second magnetic field memory 17 in a combination of pairs stored in the first magnetic field memory 16, and then the Gaussian setting box 18 is stored. When the region of use of the CRT 1 to be adjusted is selected, the magnetic field controller 15 controls the power supply 13 by finding the current value of the X, Y, Z combination already stored in the second magnetic field memory 17 for each region. Then, the appropriate voltage and current is supplied to the magnetic field generating coil 20.

Therefore, the desired magnetic field is generated in the horizontal magnetic coil 21, the vertical magnetic coil 22, and the left and right magnetic coils 23 of the magnetic field generating coil 20, and the inside of the geomagnetic field R in which the CRT 1 is transferred. The magnetic field is formed, and the magnetic field generation state is measured by the magnetic field measuring sensor 14a and the Gaussian meter 14b and displayed on the magnetic field display panel 19. At this time, when the value displayed on the magnetic field display panel 19 matches the value to be set, abnormalities such as the screen of the CRT can be appropriately adjusted.

However, as described above, the artificial geomagnetic CRT adjusting device of the prior art has several geomagnetic field R '(R) on the conveyor 11 which is an adjusting line as shown in FIG. 7 to shorten the assembly and adjustment time of the CRT. ') Will be installed. To reduce the assembly space, the installation will be made by reducing the distance between the geomagnetic field (R') and the room (R ') and between adjacent geomagnetic field (R') (R '). Since magnetic field interference occurs, a sufficient separation distance between the geomagnetic field rooms R 'and R' is required, thereby increasing the assembly and adjustment space.

That is, as shown in FIG. 8, when the geomagnetic field R 'is set to 500 mG, the distance that does not affect the adjacent geomagnetic field R' is less than 30 mG, which is about 2 m or more, and the space deviates by this distance. The assembly lines are considerably longer because the independent magnetic field rooms should be installed at each side to allow independent adjustment.

The present invention was devised to solve the above problems, and by installing a magnetic field damping coil between the geomagnetic field and the geomagnetic field, the interference between the geomagnetic fields can be minimized, thereby reducing the CRT assembly and adjustment lines. It is to provide a CRT controller using an artificial earth magnetic field that can form a uniform magnetic field in the system room to increase the reliability of screen adjustment.

The apparatus for controlling a CRT using an artificial earth magnetic field according to the present invention for realizing the above object includes a plurality of magnetic field generating means installed in front, rear, top, left, and right directions of the CRT to generate a magnetic field to form a plurality of geomagnetic fields; ; Magnetic field damping means provided on both sides of the magnetic field generating means between the geomagnetic field room and the geomagnetic field room to attenuate the magnetic field generated in the geomagnetic field room; Power supply means for applying power to the magnetic field generating means and the magnetic field attenuation means; It is characterized in that it comprises a magnetic field control means connected to the power supply means, the magnetic field generating means and the magnetic field attenuation means to control the magnetic field formation in the geomagnetic field room.

1 is a schematic configuration diagram of a typical CRT,

2 is a block diagram showing a CRT adjustment apparatus using an artificial earth magnetic field of the prior art,

3 is a block diagram showing an artificial geomagnetic field system of the prior art,

4 is a layout view of a magnetic field generating coil in the prior art,

Figure 5 is a magnetic field formation graph by the magnetic field generating coil in the prior art,

6 is a schematic wiring diagram of a magnetic field generating coil in the prior art,

7 is a diagram illustrating an installation state of a geomagnetic field and a geomagnetic field in the prior art;

8 is a magnetic field interference effect graph according to the distance between geomagnetic field rooms in the prior art,

9 is a schematic configuration diagram showing a CRT apparatus using an artificial earth magnetic field according to the present invention;

10 is a block diagram showing an artificial geomagnetic field system according to the present invention,

11 to 14 are graphs and magnetic field formation diagrams for explaining the operation and effect according to the present invention.

<Explanation of symbols for main parts of the drawings>

50: brown tube 55: conveyor

60, 60 ': magnetic field generating coil 71: power supply

72: magnetic field controller 73: Gaussian setting box

74: magnetic field display panel 75: magnetic field measurement sensor

76: Gauss meter 80,80 ': magnetic field damping coil

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention.

9 is a block diagram illustrating a CRT apparatus using an artificial geomagnetic field according to the present invention, and FIG. 10 is a block diagram of an ophthalmic earth magnetic field system according to the present invention.

The present invention is a plurality of geomagnetic field (R) by generating a magnetic field in the front and rear, up and down, left and right directions of the Brown tube 50 is installed around the conveyor 55 for conveying the Brown tube 50 and the conveyor 55 ₁ ) both side surfaces of the magnetic field generating coils 60 and 60 'forming the (R ₂ ) and the magnetic field generating coils 60 and 60' between the geomagnetic field and the room R ₁ and R ₂ . Magnetic field attenuation coils 80 and 80 'installed at the attenuating magnetic field generated in the geomagnetic field R ₁ and R ₂ , and the magnetic field generating coils 60 and 60' and the magnetic field attenuation coils 80. A power supply 71 for applying power to the power supply 80; and a magnetic field connected between the power supply 71, the magnetic field generating coils 60, 60 ', and the magnetic field attenuation coils 80, 80'. It consists of a magnetic field controller 72 that controls the formation.

As shown in FIG. 10, the magnetic field controller 72 includes magnetic field memories 72a and 72b for storing the magnitude of the magnetic field and the current value thereof, and the magnetic field generating coils 60 and 60 'and the magnetic field attenuation coils. Comparators 72c are included to compare all the magnetic field values generated from 80 and 80 '.

The magnetic field display panel 74 shows a Gaussian setting box 73 for setting the magnitude of the magnetic field in the magnetic field controller 72 and a magnetic field generated from the geomagnetic field R ₁ and R ₂ . And a magnetic field measuring sensor 75 and a Gaussian meter 76 measuring magnetic fields in the geomagnetic field R ₁ and R ₂ , respectively.

The magnetic field generating coils 60, 60 'are also as described in the four horizontal (X) magnetic field coils, the vertical (Y) a magnetic field coil, the left and right side (Z) consists of a magnetic field coil, respectively prophet of total rooms (R ₁₎ (R ₂ ) is formed.

In particular, the magnetic field damping coils 80 and 80 'are positioned on both sides of the left and right magnetic field coils of the magnetic field generating coils 60 and 60', and are the same as the magnetic field generating coils 60 and 60 '. Consists of a coil, the current is applied in a direction opposite to the current flow direction of the magnetic field generating coil (60, 60 ') through the damping coil power supply (71a) of the power supply (71).

The magnetic field attenuation coils 80 and 80 'are symmetrically at the center between the geomagnetic field room R ₁ and the room R ₂ at a point spaced apart from the magnetic field generating coils 60 and 60'. Is installed.

Accordingly, the distance between the geomagnetic field R ₁ and the geomagnetic field R ₂ is at least greater than the point at which the sum of the magnetic fields becomes 0G by the magnetic field damping coils 80, 80 ′. It is arranged so that there is no interference of the magnetic field between the room R ₁ and the geomagnetic field R ₂ .

Referring to the operation of the CRT controller using the artificial earth magnetic field according to the present invention configured as described above are as follows.

As shown in FIG. 9, between the first geomagnetic field R ₁ and the second geomagnetic field R ₂ , between the first geomagnetic field R ₁ and the first magnetic attenuation coils 80a and 80b, the second The distance between the geomagnetic field R ₂ and the second magnetic field attenuation coil 80 ′ is constantly set.

Subsequently, a current is applied to the first magnetic field damping coil 80 in a direction opposite to the magnetic field generating coil 60 of the first geomagnetic field R ₁ , and the second magnetic field damping coil 80 ′ also applies to the first magnetic field damping coil 80. Current is applied in a direction opposite to the magnetic field generating coil 60 'of the system room R ₂ .

And all the magnetic field value required by the magnetic field comparator (72c) the magnetic field values of the two earth magnetic rooms (R ₂₎ is also replaced or prophet changed a total value state current direction first prophet of total rooms (R ₁₎ is set The current value of the first geomagnetic field R ₁ and the first magnetic field attenuation coil 80 when the desired magnetic field value is maintained is read, and a current pair for the magnetic field is stored in the first magnetic field memory 72a.

In this way, all the necessary magnetic field values are repeatedly stored in the first magnetic field memory 72a and the earth magnetic field values using the CRT 50 are stored in the first magnetic field memory 72a. Is stored in the second magnetic field memory 72b in the combination (X, Y, Z directions).

Next, when the region of use of the CRT to be adjusted through the Gaussian setting box 73 is selected, the magnetic field controller 72 finds the current value of the XYZ combination already stored in the second magnetic field memory 72b for each region and supplies the power supply 71 to the power supply 71. Transfer to control the power supply 71.

Therefore, by supplying an appropriate voltage and current to the first magnetic field generating coil 60 and the magnetic field attenuation coil 80, the desired magnetic field display in the horizontal magnetic coil, vertical magnetic coil, left and right magnetic field coil of the magnetic field generating coil 60 Displayed on panel 74.

Configure the magnetic field attenuation coil 80 prophet the first contains the total rooms (R ₁₎ as described above, and then, a second current to the earth magnetic rooms (R ₂₎ method about the same as the first earth magnetic rooms (R ₁₎ a When the value is set, the first geomagnetic field R ₁ and the second geomagnetic field R ₂ are independent geomagnetic fields that do not affect each other even if the current direction changes or the magnetic field values have different values. Can be configured.

In this way, if the displayed value coincides with the value to be set, adjust the CRT separately.

The following shows the experimental results of the CRT controller using the artificial earth magnetic field according to the present invention.

2 m as shown in Figure 11 ?? When the magnetic field generating coil 60 forming a 2m geomagnetic field R and the magnetic field attenuation coil 80 of the same size installed only 10 cm from the geomagnetic field R are placed on the magnetic field generating coil 60. Applying a current of + 448A to the 500A, the magnetic field attenuation coil 80 generates a magnetic graph (A) by the magnetic field generating coil 60 and a magnetic field graph (B) by the magnetic field attenuation coil (80). The magnetic field graph C becomes the magnetic field graph C at the center of the geomagnetic field R, but the magnetic flux density is almost 0 mG outside the geomagnetic field R.

2 m with the magnetic field damping coil as shown in FIG. Two two-meter geomagnetic fields (R ₁ ) (R ₂ ) are spaced 30 cm apart, then the first geomagnetic field (R ₁ ) is fixed to 500 mG (A) and the second geomagnetic field (R ₂ ) is + It can be seen that even if the magnetic field is rapidly changed from 300 mG (B) to -300 mG (C), no influence occurs at 500 mG of the magnetic field of the _first geomagnetic room R ₁ .

In addition, in FIG. 13, even if the values of the first geomagnetic room and the second geomagnetic room are set to +300 mG, changing the value of the second geomagnetic room from +300 mG to -300 mG has no effect on the first geomagnetic room. You can see that you did not give.

In addition, as shown in FIG. 14, the uniform magnetic field region inside the geomagnetic field room R is also widely distributed as compared with the geomagnetic field of the prior art in which the magnetic field attenuation coil is not installed.

As described above, the CRT apparatus using the artificial geomagnetic field of the present invention has a magnetic damping coil installed between the geomagnetic field and the room, so that the adjustment line of the product requiring adjustment for the earth magnetic field such as the CRT is reduced and the entire assembly is performed. And to reduce the adjustment space.

In addition, the present invention can shorten the operation time by reducing the CRT movement time to be adjusted, and at the same time, the uniform magnetic field area in the geomagnetic field room is widely distributed, thereby providing an advantage of increasing productivity and reliability of the magnetic field adjustment work.

Claims (3)

A plurality of magnetic field generating means installed in front, rear, left and right directions of the CRT and generating magnetic fields to form a plurality of geomagnetic field rooms; Magnetic field damping means provided on both sides of the magnetic field generating means between the geomagnetic field room and the geomagnetic field room to attenuate the magnetic field generated in the geomagnetic field room; Power supply means for applying power to the magnetic field generating means and the magnetic field attenuation means; And a magnetic field control means connected to the power supply means, the magnetic field generating means, and the magnetic field attenuation means to control magnetic field formation inside the geomagnetic field room. The method of claim 1, The magnetic field attenuation means is a CRT apparatus using an artificial earth magnetic field, characterized in that the current is applied in a direction opposite to the current application direction of the magnetic field generating means. The method of claim 1, And said magnetic field control means comprises magnetic field comparison means for comparing magnetic field formation generated in and around the geomagnetic field by said magnetic field damping means and magnetic field generating means.