JPH10188837A - Electron gun - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electron gun having a cathode whereby a stable electron beam can be emitted which can be manufactured simply. SOLUTION: A cathode KR of an electron gun is constituted by providing a plurality of units comprising an electron emitting source 9 with one end part in a fine wire formed in needle shape to be provided with a spherical part 9a in a tip end of this needle shape and a sleeve 10 formed in almost a fine pipe shape to be mounted in a body part 9b of the electron emitting source 9. In the electron gun thus constituted, an electric field is applied to the spherical part 9a of the electron emitting source 9, to emit electrons to generate an electron beam.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electron gun mounted on a cathode ray tube used for a television receiver or a terminal display device.

[0002]

2. Description of the Related Art A picture tube used in a television includes a glass bulb formed in a funnel shape, a fluorescent screen formed on an inner surface of a main surface portion of the glass bulb, and a glass bulb opposed to the fluorescent screen. And an electron gun disposed therein.

The electron gun emits an electron beam and irradiates the electron beam on the phosphor screen to display an image. This electron gun includes a cathode having an electron emission source, a cathode structure accommodating the cathode, a plurality of grids, and a convergence electrode. For example, the electron gun has a configuration in which a first grid, a second grid, a third grid, a fourth grid, a fifth grid, and a convergence electrode are arranged at predetermined intervals from the cathode.

The electron gun configured as described above sequentially transmits electrons emitted from the cathode through grids, convergence electrodes, and the like to generate an accelerated and converged electron beam.

[0005] The cathode of the electron gun is classified into a thermionic emission type and a field emission type. Thermionic emission type cathode is
The electron emission source is heated to a high temperature to emit electrons. For example, barium oxide is used as an electron emission source. For example, as shown in FIG. 8, a thermionic emission type cathode 101 includes an electron emission source 102 and this electron emission source 102.
, And an electron emission source holder 104 configured to hold the electron emission source 102 and house the heater 103.
Thermionic emission type cathode 101 thus configured
For example, the electron is emitted by heating the heater unit 103 and heating the electron emission source 102 to around 800 ° C. via the electron emission source holder 104.

On the other hand, the field emission type cathode emits electrons by applying an electric field to an electron emission source. For example, tungsten is used for the electron emission source. In the field emission type cathode, for example, as shown in FIG. 9, a needle-shaped electron emission source 107 is disposed so as to protrude on a Si substrate 106. Then, by changing the number of electron emission sources 107 provided on the Si substrate 106, it becomes possible to change the amount of electron emission. The field emission type cathode 105 thus configured emits electrons by applying a voltage to the tip of the electron emission source 107.

[0007]

In the thermionic emission type cathode 101, the electron emission source holder 104 and a cathode structure (not shown) supporting the electron emission source holder 104 are thermally deformed by the heat of a heater 103 for heating the electron emission source 102. Occurs. For this reason, the arrangement position of the electron emission source 102 in the electron gun changes, the irradiation trajectory of the electron beam changes, and the generated electron beam becomes unstable.

In the field emission type cathode 105,
The manufacturing process of forming the electron emission source 107 in a needle shape and disposing it on a Si substrate is complicated. In order to increase the amount of emitted electrons, for example, if the number of the electron emission sources 107 provided on the Si substrate 106 is increased, the manufacturing process is further complicated.

The present invention has been made in view of the above circumstances, and provides an electron gun having a cathode that enables stable emission of an electron beam and simplifies manufacturing. The purpose is to:

[0010]

An electron gun according to the present invention comprises:
In order to solve the above-mentioned problems, one end portion is a fine wire processed into a needle shape, and the needle-shaped tip is formed into a substantially thin tube with an electron emission portion processed into a spherical shape, and a body of the electron emission portion is formed. The cathode is constituted by the sleeve for inserting and holding the portion.

As described above, the electron gun forms a cathode in which the electron emission source is inserted and held in the sleeve.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described in detail with reference to the drawings. In this example, red,
This is a field emission type electron gun configured to converge electron beams emitted from three cathodes KR, KG and KB corresponding to respective colors of green and blue by one main lens. The cathode of the electron gun is formed into an electron emission source in which one end of a fine wire is processed into a needle shape, and the needle-shaped tip is processed into a spherical shape, and a thin tube,
And a sleeve for inserting and holding the body of the electron emission source.

[0013] The electron gun, as shown in FIG. 1, the cathode structure 2 comprising the first grid G _1, the second grid G _2, a third grid G _3, a fourth grid G ₄ and the An electron gun electrode group composed of _five grids G5 and a pair of bead glasses 3 and 4 provided to face each other to support the electron gun electrode group. Specifically, in the electron gun 1, a pair of bead glasses 3 arranged in parallel,
Fourth, the second grid G ₂ , the third grid G ₃ , the fourth grid G ₄ , and the fifth grid G ₅ are arranged in a vertical line with a predetermined space. Then, in the fifth grid G _5, which is the final electrode of the electron gun electrodes, the convergence electrode 5 is attached at its distal end.

In the electron gun 1, a main lens, a so-called unipotential lens, is constituted by the third grid G _{3 to} which the anode voltage is applied, the fifth grid G ₅ and the fourth grid G ₄ to which the focus voltage is applied. You. The electron gun 1 has three cathodes KR provided in the first back side of the grid G _1, the cathode KG, an electron beam emitted from the cathode KB crossed at the center of the main lens (the center of the fourth grid G _4), The divergent electron beams are made to enter between the convergence electrodes 5 and irradiate the fluorescent screen of a cathode ray tube (not shown).

Further, as shown in FIG.
A cathode KR, a cathode KG, and a cathode KB are accommodated in one of the cathode structures 2, 2, and 2, respectively. The cathode structures 2, 2, 2 are configured to be the same. Then, this respective cathode structure 2, the first grid G ₁ is attached. Here, the first grid G ₁ is a pair of spacers 7 made of a metal plate.
At the same time, it is mounted between the support 6 of the insulating cathode structure 2 made of ceramic or the like and the second grid. Hereinafter, only the cathode structure 2 that houses the cathode KR will be described.

As shown in FIGS. 3 and 4, the cathode structure 2 is attached to a support 6 formed to accommodate the cathode KR and a front surface of the support 6 which is an electron beam emitting side. and a first pair of spacers 7, 7 which are located on opposite sides of the grid G _1, a cathode holder 8 attached to the back of the support 6, is composed of a cathode KR held by the cathode holder 8 You.

The cathode KR is a fine wire having one end formed in a needle shape, and has an electron emission source 9 having a spherical portion 9a at the needle-like tip, and an electron emission source 9 formed in a substantially thin tube shape. And a sleeve 10 for holding the electron emission source 9 through which the body portion 9b is inserted.

The electron emission source 9 includes, for example, thorium 1
A spherical portion 9a having a radius of about 10 μm is formed at the tip of a needle-like portion 9c formed of a 0.15 mm diameter and made of tungsten to which% is added.

The sleeve 10 has an inner diameter slightly larger than the diameter of the electron emission source 9 and holds the inserted electron emission source 9.

The cathode KR is connected to a unit 11 composed of an electron emission source 9 and a sleeve 10 by a sleeve 10.
The plurality of units 11 are integrated by welding. The cathode K thus configured
R is an electron emission source 9 the tip of the spherical portion 9a so as to oppose to the first grid G _1, is disposed in the support member 6.

The support 6 is made of an insulating non-metallic material such as a ceramic, for example.
It has secured insulation between the grid G _1. This support 6
Has a substantially rectangular parallelepiped shape and a large-diameter circular hole 1 in the center.
2 are provided through the member. Moreover, the support 6, the flat portion 6a of the first grid G ₁ to one end of the circular hole portion 12 is arranged is formed, the cathode K to the other end
A flat portion 6e on which a cathode holder 8 for fitting and holding R is disposed is formed.

The cathode holder 8 is formed in a substantially cylindrical shape having an inner diameter larger than the outer diameter of the cathode KR. On the inner surface of the cathode holder 8, a projection 8a for fitting and holding the cathode KR is formed. The cathode KR is fitted and held in the projection 8 a of the cathode holder 8 attached to the flat portion 6 e of the support 6, and is located in the circular hole 12 of the support 6.

As shown in FIGS. 3 and 4, the first grid G ₁ is formed as a substantially rectangular plate-like member such that its main surface has substantially the same area as the flat portion 6 a of the support 6. Have been. Then, the first grid G _1, the beam transmission holes 13 for passing an electron beam emitted from the cathode KR disposed in a circular shape hole portion 12 of the support 6 in a substantially central portion of the main surface is formed I have.

The support 6 is provided with flat portions 6b and 6c formed on both sides of the flat portion 6a so as to be positioned at the same level as the flat portion 6a. The gap between the flat section 6b and the flat section 6a and the gap between the flat section 6c and the flat section 6a are each separated by a groove 6d.

Then, the first grid G1 is attached to the support 6 with respect to the flat portion 6a, and the flat portions 6b, 6
Spacers 7, 7 are attached to c.

The spacers 7, 7 are provided on the first grid G _1.
When it restricts the second spacing width between the grid G _2,
Flat portion 6b, and is formed slightly thicker metal plate than 6c and a rectangular having substantially the same planar shape, and the first thickness of the grid G _1.

The electron gun 1 formed as described above emits electrons by applying an electric field to the cathodes KR, KG, and KB by an electric field applying means (not shown). For example, when the applied electric field is, for example, 10 ⁷ to 1
0 ⁸ V / electron by the cm cathode KR, cathodes KG, are emitted from the cathode KB.

Then, the electrons sequentially pass through all the electrodes such as the beam transmission hole 13 formed in the first grid G ₁ , the second to fifth grids G _{2 to} G _5, and the convergence electrode 5, thereby accelerating and accelerating. It becomes a focused electron beam. The electron beam is pulled by the high voltage and focuses on a fluorescent screen in a cathode ray tube (not shown).

Therefore, the electron gun 1 uses the electric field to
Since an electron is emitted by applying an electric field to the electron gun 1, a stable electron beam can be emitted without the electron emission source 9 being displaced in the electron gun 1.

Next, a method of manufacturing the cathode KR, the cathode KG, and the cathode KB will be described. For example, as described above, the cathode KR, the cathode KG, and the cathode KB are configured such that the electron emission source 9 formed by forming one end of a tungsten thin wire doped with 1% thorium into a needle shape passes through the sleeve 10. .

For example, as shown in FIG. 5, the manufacturing method is as follows. First, the tip of a raw wire 14 having a diameter of 0.15 mm, which has been sheared to a predetermined length, is ground or chemically polished to form a needle-like portion 9c.
To form For example, the raw wire 14 is formed of tungsten to which thorium is added, and the amount of thorium added is determined with reference to FIG. That is, FIG.
As shown in (1), the maximum amount of emission can be obtained, and the workability is good, and the addition amount of thorium is selected around 1%.

Further, the shape of the spherical portion 9a formed at the tip of the needle portion 9c is determined from the relationship between the tip radius and the emission amount shown in FIG. As shown in FIG. 7, the vicinity of a radius of 10 μm is selected, where the emission amount is obtained to some extent and the variation in the emission with respect to the variation in the tip radius is small. The shape, material and the like are determined in this way, and the electron emission source 9 is formed.

On the other hand, the sleeve 10 is made of, for example, a stainless material and has a diameter slightly larger than the diameter of the raw wire 14.
It is formed in a thin tube having an inner diameter of 6 mm. Also,
The sleeve 10 has an outer diameter of 0.20 mm. The sleeve 10 is formed such that its length is substantially the same as the length of the body 9 b of the electron emission source 9.

The unit 11 is formed by inserting the electron emission source 9 configured as described above into the sleeve 10. That is, the unit 11 is formed by positioning the needle-like portion 9c of the electron emission source 9 so as to protrude from the sleeve 10, and fixing the body portion 9b and the sleeve 10 by welding or pressing. Then, a plurality of units 11 configured as described above are prepared, and an integrated cathode is formed by, for example, welding or a band-like band.

Therefore, the electron gun 1 has a unit 11 that constitutes the cathode KR, the cathode KG, and the cathode KB only by inserting the electron emission source 9 having a needle-like tip into the sleeve 10 and fixing by welding or pressing. Can be formed.

The electron gun 1 includes a plurality of units 11
By simply welding or band-tightening, the electron emission source 9 can be increased or decreased to change the electron emission amount arbitrarily.
As a result, the electron gun 1 includes the cathode KR and the cathode K
The number of the electron emission sources 9 constituting the G and cathode KBs or the increase or decrease of the electron emission amount can be easily changed.

It is to be noted that the electron gun 1 is not limited to the electron emission source 9 formed of tungsten to which 1% of thorium is added. Can also be formed.

In the electron gun 1, the electron emission source 9 can be formed of another material, for example, nickel, molybdenum, diamond, niobium, lanthanum hexaboride, or the like.

The electron gun 1 is not limited to having five grids, but may be of a so-called bipotential type, for example, having four grids.

Further, the electron gun 1 is not limited to a so-called field emission type cathode which applies an electric field to the electron emission source 9 and emits electrons. , A so-called thermionic emission type cathode. in this case,
The electron emission source 9 emits electrons when heated by the heating means. As described above, since the electron emission source 9 is compatible with the field emission type cathode and the heat emission type cathode, the electron emission source for the field emission type and the electron emission source for the thermionic emission type are separately provided. There is no need to manufacture it.

[0041]

As described above, the electron gun according to the present invention is stable in that it has a cathode in which the body of the electron emission portion whose needle-like tip is machined into a spherical shape is inserted and held in a sleeve formed into a substantially thin tube. Emission of an electron beam is enabled, and manufacturing is simplified.

[Brief description of the drawings]

FIG. 1 is a front view of an electron gun according to an embodiment of the present invention.

FIG. 2 is a side view showing an attached state of each cathode structure provided in the electron gun.

FIG. 3 is a perspective view of the cathode assembly.

FIG. 4 is a sectional view of the cathode assembly.

FIG. 5 is a manufacturing process diagram showing a manufacturing process of a cathode housed in the cathode structure.

FIG. 6 is a characteristic diagram showing a relationship between an added amount of thorium and an emission amount.

FIG. 7 is a characteristic diagram showing a relationship between a tip radius and an emission amount.

FIG. 8 is a perspective view showing a conventional thermionic emission type cathode.

FIG. 9 is a perspective view showing a conventional field emission type cathode.

[Explanation of symbols]

1 electron gun, 9 electron emission source, 9a spherical part, 9b body part, 9c needle part, 10 sleeve, KR, KG, K
B Cathode

Claims (4)

[Claims] 1. An electron gun in which electrons are emitted into a vacuum by applying heat by a cathode and an electron beam is formed by the emitted electrons, wherein the cathode is a thin wire having one end processed into a needle shape. There is an electron emitting portion whose needle-shaped tip is machined into a spherical surface,
An electron gun, comprising: a substantially thin tubular shape; and a sleeve for inserting and holding a body portion of the electron emitting portion. 2. The electron gun according to claim 1, wherein the cathode is a field emission type cathode that emits electrons by applying an electric field to the electron emission section. 3. The electron gun according to claim 1, wherein said electron emitting portion is formed of a thin tungsten wire doped with thorium. 4. The electron gun according to claim 1, wherein the cathode includes a plurality of units each of which has the electron emission portion and the sleeve as a pair.