KR102477781B1 - Electron emission source and x-ray apparatus having the same - Google Patents

Abstract

An electron emission source of an X-ray apparatus according to the present invention disclosed herein includes an electrode unit for emitting electrons for generating X-rays, a gate unit for extracting electrons emitted from the electrode unit, and an insulation provided between the electrode unit and the gate unit having insulation properties. Both ends of the insulation part are bonded to the electrode part and the gate part, respectively, and bonded so as to surround at least a portion of the outer circumferential surface of the electrode part. According to this configuration, it is possible to provide an electron emission source and an X-ray apparatus including the same, which are excellent in assembly and advantageous in ensuring confidentiality.

Description

Electron emission source and X-ray device including the same {ELECTRON EMISSION SOURCE AND X-RAY APPARATUS HAVING THE SAME}

The present invention relates to an electron emission source and an X-ray device including the same, and more particularly, to an electron emission source having excellent electron emission performance with excellent airtightness and improved assembly property, and an X-ray device including the same.

In general, X-rays include an X-ray tube, which is a vacuum tube, to emit X-rays. The cathode of this X-ray tube is formed of a tungsten filament, and is heated by an electric current to emit thermal electrons. In contrast, when a high voltage of tens of thousands of volts or more is applied to the anode of the X-ray tube, the electron current emitted from the cathode moves toward the anode at high speed. At this time, when the electron flow collides with the counter electrode made of tungsten or molybdenum, the energy it has is released as X-rays.

On the other hand, in recent years, the development of X-rays using the growth of carbon nanotubes (CNTs), which are nanomaterials, as a field emitter of X-rays is in progress. A carbon nanotube is a carbon allotrope made of carbon. One carbon atom is bonded to another carbon atom in a hexagonal honeycomb pattern to form a tube, and thus is applied in various electric and electronic fields.

In an X-ray apparatus for emitting X-rays, internal airtightness and alignment of components constituting an electron emission source, such as an emitter, a cathode electrode, and a gate electrode, are major factors in quality. Accordingly, in recent years, various studies to improve electron emission quality of electron emission sources have been continuously conducted.

Korean Patent Registration No. 10-0851950 Korean Patent Registration No. 10-0490480

An object of the present invention is to provide an electron emission source in which an assembly process is improved so as to improve assembly alignment accuracy while maintaining internal confidentiality.

Another object of the present invention is to provide an X-ray apparatus including an electron emission source in which the above object is achieved.

An electron emission device according to the present invention for achieving the above object is an electrode unit for emitting electrons for X-ray generation, a gate unit for extracting electrons emitted from the electrode unit, and an electrical insulation property between the electrode unit and the gate unit. An insulation portion provided therebetween, wherein both ends of the insulation portion are bonded to the electrode portion and the gate portion, respectively, and bonded so as to surround at least a portion of the outer circumferential surface of the electrode portion.

Also, a contact area between the insulating part and the electrode part and the gate part may be joined by at least one of metalizing, brazing, and bonding.

In addition, the electrode unit includes an electron emitter and a cathode electrode provided with a support protrusion extending in a radial direction from a lower end and bent vertically upward along a circumferential direction, in which the electron emitter is stacked on an upper end to apply a negative electrode, The insulating part may have a tube shape in which a lower end is stacked on the support protrusion and is in line contact, and an inner circumferential surface is in close contact with an outer circumferential surface of the cathode electrode.

Also, the electron emission source may be formed of a metal or a carbon-based material.

In addition, the insulating part may be provided between the support protrusion and the upper surface of the cathode electrode, and a corner of the insulating part may have a chamfered surface not covering an end of the cathode electrode.

In addition, the insulating portion may be made of a ceramic material and may not cover an end portion of the electrode portion.

In addition, the gate part includes a gate mesh facing the electrode part and a gate electrode supporting an edge of the gate mesh and stacked on top of the insulating part, wherein the gate electrode forms a space between the electrode part and the electrode part. A first step bent vertically downward along the circumferential direction provided on the lower surface to be formed, and a second step extended in the radial direction from the first step and bent vertically downward along the circumferential direction, The second step may come into surface contact with one end of the insulating portion to cover at least a portion of the outer circumferential surface of the insulating portion.

In addition, a vacuum pipe providing vacuum force may be inserted through the electrode unit.

An X-ray apparatus according to a preferred embodiment of the present invention includes a hollow body, an electron emission source provided on one side of the body and emitting electrons toward the inside of the body, and the body facing the electron emission source. It is provided on the other side and includes an anode unit for generating X-rays by collision with the electrons, and the electron emission source includes an electrode unit for emitting electrons for generating X-rays, a gate unit for extracting electrons emitted from the electrode unit, and , An insulating portion having electrical insulation and provided between the electrode portion and the gate portion, wherein both ends of the insulating portion are bonded to the electrode portion and the gate portion, respectively, and bonded to cover at least a portion of the outer circumferential surface of the electrode portion.

In addition, the body portion may include a hollow chamber inside which is directly evacuated by connection with the vacuum pipe.

In addition, the anode portion may have a reflective surface colliding with the electrons, and a window for guiding the X-rays guided from the reflective surface to the outside of the body portion may be provided in the body portion.

According to the present invention having the configuration as described above, first, both ends of the insulating portion are bonded to the electrode portion and the gate portion, respectively, and bonded so as to cover the outer circumferential surface of the electrode portion, thereby improving the airtightness of the electron emission source. In particular, since contact regions between the insulating part, the electrode part, and the gate part are all bonded, a high vacuum state can be maintained, and electron emission efficiency can be improved.

Second, since the insulating part is provided between the electrode part and the gate part by using bonding force rather than fixing force in the direction of gravity, it is possible to improve contact resistance increase, part contamination, and part alignment deterioration. Through this, it can contribute to shortening the assembly process time, improving the completeness of parts, and improving the manufacturing cost.

Third, since the vacuum pipe is directly connected to vacuum the inside of the X-ray device, it is possible to maintain a high-quality vacuum.

1 is a perspective view schematically illustrating an X-ray apparatus having an electron emission source according to an embodiment of the present invention.
2 is a schematic cross-sectional view of an electron emission source of the X-ray apparatus shown in FIG. 1; And,
FIG. 3 is an exploded view schematically illustrating the electron emission source shown in FIG. 2 .

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. However, the spirit of the present invention is not limited to such embodiments, and the spirit of the present invention may be proposed differently by adding, changing, and deleting components constituting the embodiments, but this is also included in the spirit of the present invention. It will be.

Figure 1 schematically shows an x-ray apparatus 1 having an electron emission source 20 in one preferred embodiment of the present invention. As shown in FIG. 1 , an X-ray apparatus 1 according to an embodiment of the present invention includes a body part 10 , an electron emission source 20 and an anode part 30 .

The body portion 10 includes a hollow cylindrical chamber in which a space is provided, and the inside is in a vacuum state. One side of the body portion 10 is provided with a window 11, which is an entrance for X-rays emitted from the inside of the body portion 10 to the outside. The window 11 may be formed of a metallic material such as beryllium or aluminum or a glass material coated with a fluorescent material. In this case, when the window 11 is formed of a metal material such as beryllium, a filter tube may be used to emit only X-rays having a predetermined wavelength or less. In addition, when the window 11 is formed of a glass material coated with a fluorescent material, visible light may be emitted through the window 11 .

The body portion 10 may be formed of a non-metallic material. In this way, when the body portion 10 is made of a non-metallic material, insulation is secured to prevent a high-voltage current of 70,000 volts or more applied to the electron emission source 20 to be described later from flowing along the inner wall of the body portion 10. can

The electron emission source 20 is provided on one side of the inside of the body 10 to emit electrons. Here, the electron emission source 20 includes an electron emission module or an electron gun that emits electrons to generate X-rays, and is provided below the body portion 10 . The electron emission source 20 is exemplified as emitting electrons in a carbon nanotube (CNT)-based field emission method from the inside of the vacuum body 10 . However, it is not necessarily limited thereto, and a modified example in which the electrode unit 210 is applied to a light source generating light is also possible. The configuration of this electron emission source 20 will be described later in detail.

The anode unit 30 generates light such as X-rays by colliding with electrons emitted from the electron emission source 20 and guides them to the outside of the body unit 10 . Light including X-rays generated from the anode unit 30 may vary depending on the material of the anode unit 30 and the magnitude of the voltage applied to the X-ray device 1, specifically among X-rays, visible rays, infrared rays, and ultraviolet rays. can be any one

The anode part 30 is provided on the other side of the body part 10, that is, on the upper part, to face the electron emission source 20. In addition, the anode part 30 is provided with a reflection surface 31 to generate X-rays (L) or light by collision with electrons and guide them to the outside of the body part 10 . Since the configuration of the anode unit 30 having the reflective surface 31 is not the gist of the present invention, a detailed description thereof will be omitted.

For reference, the reflective surface 31 of the anode unit 30 is formed of the same material as the anode unit 30 or formed of a fluorescent material to generate at least one of X-rays, visible rays, infrared rays, and ultraviolet rays. In addition, when the reflective surface 31 is formed of a material such as glass rather than metal, a modified example of generating light for illumination by collision with electrons is also possible.

Meanwhile, the electron emission source 20 provided in the above-described X-ray apparatus 10 will be described in more detail with reference to FIGS. 2 and 3 .

As shown in FIGS. 2 and 3 , the electron emission source 20 includes an electrode part 210 , a gate part 220 and an insulation part 230 .

The electrode unit 210 emits electrons for generating X-rays. To this end, the electrode unit 210 includes an electron emission source 211 and a cathode electrode 212 .

The electron emitter 211 is a kind of emitter that emits electrons. The electron emission source 211 is formed as a planar light source in the form of a thin plate, and faces the above-described anode part 30 to emit electrons toward the anode part 30 . Here, the electron emission source 211 is preferably a carbon-based material or metal formed on silicon, metal, or carbon-based material. In addition, the electron emitter 211 is exemplified as capable of emitting high current per unit area by using a carbon nanotube (CNT), which is a nanomaterial.

For reference, the edge of the electron emission source 211 is protected by being wrapped by the protective member 211a, and edge effects can be prevented.

The cathode electrode 212 is a kind of negative electrode that applies a cathode to the electron emission source 211 . To this end, the material of the cathode electrode 212 is a metal electrode including an alloy or a single transition metal such as nickel, iron, and cobalt.

The cathode electrode 212 has a cathode hole 212a penetrating in an axial direction, and a vacuum hole 212b into which a vacuum pipe 240 is inserted to communicate with the cathode hole 212a. At this time, the diameter of the vacuum hole 212b into which the vacuum pipe 240 is inserted may have a larger shape than the diameter of the cathode hole 212a, but it is natural that it is not limited to the illustrated example.

The cathode electrode 212 has a through-shape in the axial direction so that the cathode hole 212a and the vacuum hole 212b communicate with each other. At this time, a vacuum pipe 240 for directly providing vacuum pressure to the body 10 is inserted into the vacuum hole 212b, so that vacuum pressure is applied to the inside of the body 10 through the communicating cathode hole 212a. will be provided Therefore, the X-ray apparatus 1 described in the present invention is directly evacuated by a vacuum method by connection with the vacuum pipe 240, which is advantageous in maintaining a high level of vacuum.

On the other hand, a cross hole 213 is formed through the upper surface 212c of the cathode of the cathode electrode 212, and the electron emission source 211 is seated on the upper surface 212c of the cathode where the cross hole 213 is provided so that the cathode is applied. do.

The gate part 220 extracts electrons emitted from the electrode part 210 . The gate portion 220 is located above the electron emitter 211 and includes a gate mesh 221 and a gate electrode 222 .

The gate mesh 221 is provided in a relatively thin plate shape and has a metal mesh shape. An edge of the gate mesh 221 is supported by the gate electrode 222 . At this time, a gate hole 223 is formed through the center of the gate electrode 222, and a gate mesh 221 is provided in the gate hole 223, so that emission of extracted electrons is not interfered with. Here, the gate mesh 221 may be spaced apart from the electron emitter 211 by a predetermined interval, induce an electric field to be well applied to the center of the electron emitter 211, and emit light from the electron emitter 211. uniformly extracts electrons.

On the other hand, it is preferable that the gate mesh 221 has a plurality of openings formed between the metal meshes, and the shape of the openings is formed in a hexagonal honeycomb shape. When the opening of the gate mesh 221 is formed in a hexagonal shape, electrons are stably discharged without colliding with the metal mesh, so that the gate mesh 221 can efficiently extract electrons.

Meanwhile, a first step 224 is provided on the lower surface of the gate electrode 222 to provide a gap between the gate mesh 221 and the electron emitter 211 . The first step 224 is provided on the lower surface of the gate electrode 222 in a vertical downward direction along the circumferential direction. Due to the first step 224, a spaced apart space can be formed between the electron emission source 211 and the gate portion 220, so that generated from the component during long-term use, for example, from the electron emission source 211 Contamination due to contaminants such as carbon powder can be prevented.

In addition, a second step 225 extending in a radial direction from the first step 224 and bent vertically downward along the circumferential direction is provided on the gate electrode 222 . The second step 225 surrounds at least a portion of the outer circumferential surface of the insulating portion 230 to be described later and makes surface contact.

The insulating part 230 has electrical insulating properties and is provided between the electrode part 210 and the gate part 220 . The insulation unit 230 may be made of an insulating material such as ceramic, but the material is not limited thereto. The insulating part 230 is stacked between the electrode part 210 and the gate part 220, both ends are bonded to the electrode part 210 and the gate part 220, respectively, and at least a part of the electrode part 210 It is bonded so as to cover the outer circumferential surface.

Here, the insulating part 230 is laminated on the support protrusion 214 of the cathode electrode 212 and has a tube shape closely adhered to the cathode outer circumferential surface 212d of the cathode electrode 212 . The support protrusion 214 of the cathode electrode 212 extends in a radial direction from the lower end of the cathode electrode 212 and is bent vertically upward along the circumferential direction. In this way, the insulating lower surface 232 of the insulating part 230 is laminated on the supporting protrusion 214 extending from the lower end of the cathode electrode 212 and protruding, and is in line contact with it. At this time, the insulating lower surface 232 of the insulating part 230 and the support protrusion 214 are joined by at least one of metalizing, brazing, and bonding.

That is, the insulating part 230 is stacked in the direction of gravity with respect to the support protrusion 214 of the cathode electrode 212 and is bonded to each other. In this way, when the insulating lower surface 232 of the insulating part 230 is laminated and bonded so as to be in line contact with the support protrusion 214 integrally extending from the cathode electrode 212, a gap between the insulating part 230 and the cathode electrode 212 is formed. Confidentiality can be secured regardless of the dimensional accuracy of

In addition, the insulating inner circumferential surface 231 of the insulating portion 230 is bonded to the cathode outer circumferential surface 212d of the cathode electrode 212 so as to be in close contact with it. At this time, the insulating inner circumferential surface 231 of the insulating portion 230 and the cathode outer circumferential surface 212d of the cathode electrode 212 are mutually bonded by at least one of the above-described bonding methods, for example, metallization.

On the other hand, the insulating part 230 has a height extending from the support protrusion 214 to the cathode upper surface 212c of the cathode electrode 212, so that the electron emission source stacked on the cathode upper surface 212c of the cathode electrode 212 It is good to not interfere with (211). That is, since the electron emission source 211 that emits electrons is not covered by the insulating portion 230, it is preferable not to electrically interfere with the electron emission operation of the electron emission source 211.

In addition, the lower end of the gate electrode 222 is stacked on the insulating upper surface 233 of the insulating part 230, and the second step 225 protruding from the lower end of the gate electrode 222 is the insulating part 230. Surface contact is made so as to cover at least a portion of the outer circumferential surface 234 . At this time, the second step 225 is shown and exemplified as covering only the upper region of the insulating outer circumferential surface 234 of the insulating portion 230, that is, a region near the insulating upper surface 233 of the insulating portion 230, but is not limited thereto. don't The contact area between the second step 225 of the gate electrode 222 and the insulating outer circumferential surface 234 of the insulating part 230 is also bonded to each other by at least one of the above-described bonding methods.

For reference, as illustrated in FIG. 3 , corners of the insulating portion 230 are provided as chamfered surfaces 235 that are obliquely chamfered. Among these chamfered surfaces 235, due to the chamfered surface 235 provided between the insulating upper surface 233 of the insulating part 210 and the insulating inner circumferential surface 231, the insulating part 230 is the upper region of the electrode part 210. The cathode upper surface 212c of the cathode electrode 212 is not covered. Therefore, the insulating part 230 exposes the end of the electrode part 210 without covering it.

A method of assembling the electron emission source 20 according to the present invention having the above structure will be summarized with reference to FIGS. 2 and 3 as follows.

First, the insulating part 230 is stacked on the support protrusion 214 of the cathode electrode 212 of the electrode part 210 to make line contact, and the contacted areas are bonded to each other. At this time, the cathode outer circumferential surface 212d of the cathode electrode 212 and the insulating inner circumferential surface 231 of the insulating portion 230 are also closely adhered to each other and bonded. In addition, the gate electrode 222 of the gate unit 220 is stacked on the insulating upper surface 233 of the insulating unit 230 in a state where the gate mesh 221 is provided in the gate hole 223 . Here, the second step 225 of the gate electrode 222 is brought into close contact with the upper region of the insulating outer circumferential surface 234 of the insulating part 230 and is bonded to each other. Therefore, the support protrusion 214 of the cathode electrode 212 is formed on the lower surface of the insulating part 230, the cathode outer circumferential surface 212d of the cathode electrode 212 is formed on the inner circumferential surface 231, and the upper insulating surface of the insulating part 230 is formed. 233 and an upper region of the insulating outer circumferential surface 234 come into contact with the second step 225 of the gate electrode 222 to be bonded to each other.

In this way, the insulating part 230 is coupled between the electrode part 210 and the gate part 220 by mutual bonding force, not by pressing and fixing force in the direction of gravity, so that contact resistance between the respective parts can be reduced. In addition, the insulation unit 230 can ensure airtightness between the electrode unit 210 and the gate unit 220, so that a high level of vacuum can be maintained. At this time, as the vacuum pipe 240 directly vacuums the inside of the body 10, it is more advantageous to maintain a high-quality vacuum state.

In addition, compared to the conventional side coupling method between the cathode electrode 212 and the insulation portion 230, the method in which the insulation portion 230 is stacked so as to be in line contact with the support protrusion 214 provides relatively accurate processing of each part. Dimensions are not required. Accordingly, it is possible to improve assembly efficiency along with shortening process time, improving device completeness, and improving manufacturing cost.

As described above, although it has been described with reference to the preferred embodiments of the present invention, those skilled in the art will variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the claims below. You will understand that it can be done.

1: X-ray device 10: body
11: window 20: electron emission source
30: anode part 210: electrode part
211: electron emission source 212: cathode electrode
220: gate part 221: gate mesh
222: gate electrode 230: insulator
240: vacuum pipe

Claims (11)

an electrode unit that emits electrons for generating X-rays;
a gate unit extracting electrons emitted from the electrode unit; and
an insulating portion having electrical insulation and provided between the electrode portion and the gate portion;
Including,
Both ends of the insulating part are bonded to the electrode part and the gate part, respectively, and bonded so as to surround at least a portion of the outer circumferential surface of the electrode part,
the electrode part,
electron emitters; and
a cathode electrode having a support protrusion extending radially from a lower end and bent vertically upward along a circumferential direction;
Including,
The electron emission source of claim 1 , wherein a lower end of the insulating part is stacked on the support protrusion and has a tube shape in which an inner circumferential surface is in close contact with an outer circumferential surface of the cathode electrode. According to claim 1,
The electron emission source of claim 1 , wherein a contact area between the insulating part and the electrode part and the gate part is bonded by at least one of metalizing, brazing, and bonding. delete According to claim 1,
The electron emission source is formed of a metal or a carbon-based material. According to claim 1,
The insulating part is provided between the support protrusion and the upper surface of the cathode electrode, and a corner of the insulating part has a chamfered surface that does not cover an end portion of the cathode electrode. According to claim 1,
The insulator is made of a ceramic material and does not cover an end portion of the electrode. According to claim 1,
the gate part,
a gate mesh facing the electrode unit; and
a gate electrode supporting an edge of the gate mesh and stacked on top of the insulating portion;
Including,
The gate electrode includes a first step bent vertically downward along a circumferential direction provided on a lower surface to form a space between the electrode part and a first step extending in a radial direction from the first step and perpendicular to the circumferential direction. An electron emission source including a second step bent downward, wherein the second step comes into surface contact with one end of the insulating portion and surrounds at least a portion of the outer circumferential surface of the insulating portion. According to claim 1,
The electron emission source of claim 1 , wherein a vacuum pipe providing a vacuum force is inserted through the electrode part. a hollow body;
an electron emission source according to any one of claims 1, 2, and 4 to 8, provided on one side of the body and emitting electrons toward the inside of the body; and
an anode portion provided on the other side of the body portion to face the electron emission source and generating X-rays by collision with the electrons;
X-ray device comprising a. According to claim 9,
The X-ray apparatus including a hollow chamber inside which the inside of the body is directly evacuated by connection with the vacuum pipe. According to claim 9,
The anode unit has a reflective surface colliding with the electrons, and a window for guiding the X-ray guided from the reflective surface to the outside of the body portion is provided in the body portion.

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