KR100254727B1 - Cathode for crt - Google Patents

Abstract

PURPOSE: A cathode is provided to be capable of minimizing a heat amount transferred to other parts through a sleeve by coating on an outer side a material having a thermal conductivity more than that of the cathode. CONSTITUTION: A sleeve(101) transfers the heat of a heater, and a cap(103) is supplied with the heat of the heater from the sleeve(101) to emit hot electrons. The cap(103) is coated by an electron emitting material(102). A holder(104) supports the sleeve(101) and the cap(103). A material(105) is coated on an outer surface of the sleeve(101) in order to minimize the amount of heat transferred to other parts through the sleeve(101). The material(105) has a thermal conductivity more than that of the cathode. The material(105) can be coated on an upper part of the holder(104) or on the cap(103).

Description

Cathode for Cathode Ray Tube

The present invention relates to a cathode of a cathode ray tube, and more particularly to a cathode for a cathode ray tube that changes the structure of the cathode to minimize heat loss of the cathode.

As shown in FIG. 1, a general cathode ray tube includes a panel 2 having a red, green, and blue fluorescent film 1 coated on its inner surface, and a funnel 3 fused to a rear end of the panel 2. A deflection yoke (7) mounted on the neck portion (4) of the funnel (3) to deflect the electron beam (5) and the electron beam (5) emitted from the electron gun (6); It consists of a shadow mask 8 in which the electron beam 5 deflected by the deflection yoke 7 selectively passes and color discriminates.

The electron gun 6 has a heater 9 which generates heat when power is applied, a cathode 10 which radiates hot electrons by receiving heat from the heater 9 into which the heater 9 is inserted, and the cathode 10. The first to sixth electrodes (11 to 16) for concentrating and accelerating the hot electrons were configured so that the hot electrons radiated therefrom pass through the openings of the shadow mask 8 and strike the fluorescent film 1 smoothly.

As shown in FIG. 2, the cathode 10 has a sleeve 17 for generating heat when a power is applied to the cathode 9 to transfer heat from the heater 9 to the upper portion, and the sleeve. The cap 19 is formed of a cap 19 coated with an electrospinning material 18 so as to radiate heat electrons from 17, and a holder 20 for supporting the sleeve 17 and the cap 19.

In addition, as shown in FIG. 3, the mounting structure of the cathode 10 includes a cathode 10 into which a cathode heating heater 9 is inserted, and an eyelet 21 for fixing the cathode 10. ) And a bead supporter supporting the bead glass 22 and the eyelet 21 to fix the electron gun mount and at the same time maintain a constant distance between electrodes of the electron gun 6. (Bead Supporter) 23, a first electrode 11 for condensing hot electrons radiated from the cathode 10, and a second electrode 12 for accelerating hot electrons passing through the first electrode 11; Equipped.

In addition, Figure 4 shows an embodiment of various cathodes used in the cathode ray tube, Figure 4 (a) is a sleeve and the holder integrated cathode 30, Figure 4 (b) is a cap, sleeve, holder 4 is a one-piece negative electrode 40, and (c) of FIG. 4 shows the ribbon type negative electrode 50 connecting three spaces between the sleeve and the holder with three thin metal ribbons.

Referring to the action of the cathode for a conventional cathode ray tube configured as described in detail as follows.

First, when a constant voltage is applied to the heater 9, the heater 9 generates heat, and this heat is applied to the cap 19 covered on the top of the sleeve 17 through the sleeve 17 of the cathode 10. When delivered, hot electrons are emitted from the electron-emitting material 18.

The hot electrons radiated from the electron-emitting material 18 are focused by the first electrode 11, accelerated while passing through the second to sixth electrodes 12 to 16, and then deflected by the deflection yoke 7, and the shadow While passing through the mask 8, the fluorescent film 1 is blown in the state where color screening is performed, and the image is reproduced.

In this way, whether the heat generated from the heater 9 is well transmitted to the electron-emitting material 18 will have a significant effect on the characteristics of the electron gun (6).

However, such a conventional cathode not only transfers heat generated from the heater to the cap or the electrospinning material of the cathode, but also to the sleeve and the holder of the cathode, and the heat transferred to the sleeve and the holder is transferred to the eyelet, and gradually Heat is also transferred to the bead supporter to thermally deform the bead glass, and the first electrode and the second electrode fixed to the bead glass also undergo thermal deformation, which also changes the pore size of the first electrode and the second electrode. It will have a different value from.

This results in a change in E _kco , as shown by E _kco equation

Here, E _kco is a bright point voltage, k is a proportional constant, D is the first electrode pore, d ₁ is the gap between the cathode and the first electrode, d ₂ is the gap between the first electrode and the second electrode, t is One electrode thickness, E _c2 , represents the voltage applied to the first electrode.

Therefore, the deformation of the structural dimensions of the first electrode and the second electrode due to the _heat deformation causes the E _kco to change, resulting in a deterioration of focus, and also a larger heater to cover this heat loss. Since the voltage must be applied, the power loss increases, and the life of the heater is shortened.

In view of this point, the present invention coats a material having a lower thermal conductivity than that of the negative electrode, that is, a material having a thermal conductivity of 1.0 × 10 ^-4 / c or less, on the outer surface of the negative electrode, and the other parts through the sleeve. The purpose is to minimize the amount of heat transferred to the furnace.

1 is a longitudinal cross-sectional view of a typical cathode ray tube.

2 is a configuration diagram of a cathode for a conventional cathode ray tube.

Figure 3 is a mounting structure of the cathode for a typical cathode ray tube.

4 is a configuration diagram of cathodes used in a conventional cathode ray tube,

(A) The sleeve holder integrated cathode.

(B) Cap, sleeve, holder integrated cathode.

(C) is a ribbon cathode.

5 is a configuration diagram of a cathode for a cathode ray tube of the present invention.

6 is a configuration diagram showing another embodiment of the present invention,

(A) The sleeve holder integrated cathode.

(B) Cap, sleeve, holder integrated cathode.

(C) is a ribbon cathode.

Explanation of symbols on the main parts of the drawings

101, 201, 301, 401: sleeve 102: electron-emitting material

103, 204, 304: Cap 104, 203, 303, 403: Holder

105, 202, 302, 402: coating 404: metal ribbon

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

5 is a schematic diagram of a cathode for a cathode ray tube according to the present invention, a sleeve 101 for inserting an inserted heater (not shown in the drawing) to transfer heat of the heater to an upper portion thereof, and the sleeve 101. The cap 103 is coated with an electron-emitting material 102 so as to radiate hot electrons from the heat, and a holder 104 supporting the sleeve 101 and the cap 103.

In addition, to minimize the amount of heat transferred to the other parts through the sleeve 101, the outer surface of the sleeve 101 is coated with a material (hereinafter coating) 105 having a lower thermal conductivity of the cathode, the sleeve Not only the coating 105 may be coated on a substantial upper portion of the holder 104 supporting the 101 and the cap 103, but the coating 105 may also be coated on the cap 103.

When coating the outer surface of the holder 104, care should be taken to facilitate the welding to the eyelet (not shown) welds of the holder 104.

Referring to the operation of the present invention configured as described in detail as follows.

First, when a constant voltage is applied to the heater, the heater generates heat, and when the heat is transferred to the cap 103 covered on the top of the sleeve 101 through the sleeve 101 of the cathode, it is applied to the top of the cap 103. The hot electrons are emitted from the electron emitting material 102.

The hot electrons radiated from the electron-emitting material 102 are focused and accelerated through a plurality of electrodes, are deflected by the deflection yoke, and hit the fluorescent film in a state where color discrimination is made while passing through the shadow mask to reproduce an image. .

At this time, the heat generated in the heater is transferred to the sleeve 101 of the negative electrode as well as the cap 103 or the electron-emitting material 102 of the negative electrode, the heat transferred to the sleeve 101 to the eyelet and the bead supporter This heat causes a problem of heat deformation in the bead glass and the electrode.

In order to solve this problem in the present invention by coating the coating 105 on the outer surface of the sleeve 101 to minimize the heat loss generated in the cathode heat transfer process of the heater.

Since the sleeve 101 and the eyelet, the eyelet and the bead supporter are in contact with each other, the heat transferred to the sleeve 101 during the cathode heat transfer process of the heater is naturally transferred to the contact part, but is applied to the outer surface of the sleeve 101. The resulting coating 105 reduces the amount of eyelet or bead supporter heat transfer of the sleeve 101 to a minimum.

As a result, not only the change of E _kco due to heat is reduced but also the white balance has a better result than before.

Here, the coating 105 does not necessarily need to be coated only on the sleeve 101, and the coating 105 may also be coated on the upper portion of the holder 104 including the sleeve 101 or on the cap 103 portion. If you can get a better effect.

However, care should be taken when covering the holder 104 to cover the eyelet welds of the holder 104 to facilitate welding.

Another embodiment of the present invention will be described with reference to FIG. 6.

6A is a sleeve holder integrated negative electrode, and (B) is a sleeve holder integrated negative electrode, and an example in which coatings 202 and 302 are coated on the outer surface of the sleeve 201 and 301 is shown. In addition to the sleeves 201 and 301, the upper surface of the holders 203 and 303 or the caps 204 and 304 may be coated to provide a better effect. In this case as well, the covering of the eyelet welds of the holders 203 and 303 should be avoided.

6 (c) shows a ribbon type cathode connected by a thin metal ribbon 404 between the sleeve 401 and the holder 403. In this case, the thin metal ribbon 404 on the outer surface of the sleeve 401 is formed. The coating 402 is coated while leaving a portion to be welded, and the metal ribbon 404 may be coated with one side of the metal ribbon 404 itself, or may be coated with the bottom of the holder 403 to be used in parallel.

As described above, the present invention coats a material having a lower thermal conductivity than the material of the cathode on the outer surface of the sleeve and the outer surface of the holder or the cap, thereby minimizing heat loss generated in the cathode heat transfer process of the heated heater. In addition, there is an effect to prevent the thermal deformation caused by this.

Claims (3)

In the cathode for the cathode ray tube comprising a sleeve receiving heat from the inserted heater, a cap coated with an electron-emitting material to radiate hot electrons by receiving heat from the sleeve, and a holder for supporting the sleeve and the cap, The cathode for the cathode ray tube, characterized in that the outer surface of the cathode is coated with a material having a lower thermal conductivity than the material of the cathode. The method of claim 1, The material having a lower thermal conductivity than the material of the cathode is a cathode for a cathode ray tube, characterized in that applied to the outer surface of the sleeve, the holder including the sleeve, the outer surface of the cap. The method of claim 1, The cathode for the cathode ray tube, characterized in that the thermal conductivity of the material applied to the outer surface of the cathode is 1.0 × 10 ^-4 / c or less.

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