KR20200077854A - Dual x-ray source unit and dual x-ray apparatus - Google Patents

Abstract

The present invention relates to a dual X-ray source unit having a source unit generating at least two electrons and a dual X-ray device and, more specifically, to a dual X-ray source unit capable of selectively using source units of different sizes or source units made of different materials, and a dual X-ray device. The dual X-ray source unit comprises: source units generating electrons; a focusing unit provided with at least two installation grooves in different sizes and selectively using one of the source units inserted and aligned to the installation grooves to focus the generated electrons outside, wherein the installation grooves are in a shape corresponding to the source units so that the source units may be inserted and aligned; a focusing body surrounding the outer circumferential surface of the focusing unit with an outer wall; and an electrode unit located in the installation grooves and providing a voltage to the source units to enable electron emission of the source units.

Description

Dual X-ray source unit and dual X-ray device {DUAL X-RAY SOURCE UNIT AND DUAL X-RAY APPARATUS}

The present invention relates to a dual X-ray source unit and a dual X-ray apparatus equipped with a source unit generating at least two electrons, and specifically, a dual X-ray source unit capable of selectively using a source unit having different sizes or a source unit made of different materials. And a dual x-ray apparatus.

In general, an X-ray tube is a vacuum tube for generating X-rays. The cathode of the X-ray tube is formed of tungsten filament, and heated by electric current to emit thermal electrons. In contrast, when a high voltage of tens of thousands of volts or more is applied to the positive electrode of the X-ray tube, electrons emitted from the negative electrode move toward the positive electrode at high speed. At this time, when the electrons collide with the counter electrode made of tungsten, molybdenum, etc. of the anode, the energy possessed is emitted by X-rays.

Observing human tissues using a radiological approach has advantages such as non-invasiveness.

As a result, it is giving great benefits to human civilization. In addition, due to the biotechnological and medical departments' radiological approaches, observations of tissues ranging from millimeters to several micrometers have contributed greatly to many research and development activities and to improving human health.

However, the conventional radiometer having a micrometer-sized resolution has a limitation in that it is difficult to observe microstructure due to a lack of spatial resolution, and thus must be observed using a huge radiation light utilizing a particle accelerator. In addition, the conventional micro x-ray apparatus has a limitation in application to various imaging devices due to a lack of emission x-ray flux by using a filament-based electron emission source.

Accordingly, in recent years, various researches capable of photographing high-quality X-rays have been continuously conducted.

Domestic registered patent publication No. 10-1341672 (Registration date: 2013.12.09) Domestic registered patent publication No. 10-1701047 (Registration date: 2017.01.23)

The present invention is to provide an X-ray source unit capable of selectively electric field according to the size and thickness of the irradiated object.

The present invention seeks to combine or selectively use filaments and CNTs that generate electrons.

The present invention is to provide an X-ray apparatus having an X-ray source unit for which the above object has been achieved.

The present invention for achieving this object is provided with a source portion for generating electrons, and at least two installation grooves in which the source portion is inserted and aligned in a shape corresponding to the source portion in different sizes, and the installation groove A focusing part for focusing the electrons generated by selectively using any one of the source parts aligned and inserted into the focusing body, and a focusing body surrounding the outer peripheral surface of the focusing part with an outer wall, and the installation groove, wherein the source part It includes an electrode portion to provide a voltage to enable electron emission of the source portion.

Preferably, in the present invention, the source unit generates the electrons in at least one of a filament-based thermal electron emission method or a carbon nanotube (CNT)-based field emission method.

Preferably, in the present invention, the focusing unit is provided with a first inclined surface and a second inclined surface that are connected in a curved shape with the upper surfaces facing each other, and the first inclined surface so that the source portion can be inserted into the installation groove A first installation groove and a second installation groove are respectively formed on the second inclined surface.

Preferably, in the present invention, the focusing body, the outer wall is surrounded by forming a spaced apart from the focusing portion, a step is formed in the gap.

Preferably, in the present invention, the electrode portion passes through one surface of the focusing portion toward the installation groove so as to correspond to the source portion, and is characterized in that two electrodes having different polarities are disposed in the installation groove.

Preferably, in the present invention, the electrode portion is formed with a coupling portion that is detachably coupled to the terminal provided on the source portion to enable replacement of the source portion.

Preferably in the present invention, the hollow body unit, and located on one side of the body unit, the dual X-ray source unit for emitting electrons and located on the body unit to face the dual X-ray source unit, the electronic And an anode unit for guiding X-rays or light generated by collision with the outside of the body unit, wherein the dual X-ray source unit includes a source unit for generating electrons, and the source unit in a shape corresponding to the source unit. At least two installation grooves to be inserted and aligned to be provided in different sizes, and a focusing unit to focus the electrons generated by selectively using any one of the source portions inserted and aligned in the installation groove, the Surrounding the outer circumferential surface of the focusing portion with an outer wall, the focusing portion and the outer wall are spaced apart from each other and provided in the focusing body and the installation groove where a step is formed, and the source portion emits electrons by providing voltage to the source The dual X-ray source unit coupled to the body unit includes an electrode unit enabling the insertion, and the outer peripheral surface of the body unit is inserted and coupled to the step formed in the focusing body.

Preferably, in the present invention, the dual X-ray source unit and the anode unit coupled with the body unit are brazed, and the body unit to which the dual X-ray source unit and the anode unit are combined is inside a vacuum atmosphere. To form.

Preferably, in the present invention, the source unit generates the electrons in at least one of a filament-based thermal electron emission method and a carbon nanotube (CNT)-based field emission method.

Preferably, in the present invention, the focusing unit is provided with a first inclined surface and a second inclined surface that are connected in a curved shape with the upper surfaces facing each other, and the first inclined surface so that the source portion can be inserted into the installation groove A first installation groove and a second installation groove are respectively formed on the second inclined surface.

Preferably, in the present invention, the electrode portion passes through one surface of the focusing portion toward the installation groove so as to correspond to the source portion, and is characterized in that two electrodes having different polarities are disposed in the installation groove.

Preferably, in the present invention, the electrode portion is formed with a coupling portion that is detachably coupled to the terminal provided on the source portion to enable replacement of the source portion.

Preferably, in the present invention, the bonding surface of the dual X-ray source unit and the anode unit coupled to the body unit is combined by a brazing method.

In the dual X-ray source unit according to the present invention, the source portion is inserted into at least two installation grooves provided in the focusing portion, and the source portion can be selectively used by installing at least one of a filament or a carbon nanotube (CNT).

According to the present invention, since the source parts for generating electrons are made of different sizes, X-ray imaging is performed under optimal conditions by selecting the source parts according to the conditions of the irradiated object.

According to the present invention, X-rays for various conditions are selected by using a plurality of source units capable of generating electrons by at least one of a field emission method using thermal electrons or nanocarbon tube (CNT) growth obtained by heating a filament. There is an effect that the release efficiency is improved.

1 is a perspective view of a dual X-ray apparatus according to the present invention,
Figure 2 is an exploded perspective view of a dual X-ray apparatus according to the present invention,
3 is a detailed view of the focusing unit seated by the CNT of the dual X-ray source unit according to the present invention;
Figure 4 is a detailed view of the focusing unit seating the filament of the dual X-ray source unit according to the present invention,
Figure 5 is an exploded perspective view of the focusing unit seated by the CNT of the dual X-ray source unit according to the present invention,
6 is a cross-sectional view of A-A' for the dual X-ray apparatus shown in FIG. 1;

The specific structure or functional descriptions presented in the embodiments of the present invention are exemplified for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. Also, it should not be construed as being limited to the embodiments described herein, but should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

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

1 and 2 relates to a perspective view schematically showing a dual X-ray apparatus according to the present invention and an exploded perspective view of the dual X-ray apparatus.

The dual X-ray apparatus 1 includes a body unit 10, a dual X-ray source unit 20, and an anode unit 30, preferably a hollow body unit 10 and one side of the body unit 10 Located on the body unit 10 to face the dual X-ray source unit 20 and the dual X-ray source unit 20 that emit electrons (E), and X-rays generated by collision with the electrons (E) L) or light (L) is composed of an anode unit 30 that guides the body unit 10 to the outside.

The body unit 10 is provided in a hollow shape with a space formed therein, and the dual X-ray source unit 20 is located at the bottom of the body unit 10, and the anode unit 30 is located at the top. In the body unit 10, the side portion 12 of the body unit 10 is combined with the dual X-ray source unit 20, and the side portion 12 has a curved cylindrical shape corresponding to the shape of the dual X-ray source unit 20. To form.

The side portion 12 is made of an insulating material that is a non-metal such as ceramic or glass, and it would be better to use a material that prevents electrical interference with electrons generated from the dual X-ray source unit 20.

On the other hand, the side portion 12 is provided with an exit (not shown) of X-rays emitted from the inside of the body unit 10 to the outside. The doorway is made of glass, and metal or fluorescent materials such as beryllium and aluminum may be applied to the surface. That is, when the door is coated with a metal material, filtering is performed so that only X-rays having a predetermined wavelength or less are emitted, and when applied with a fluorescent material, only visible light is emitted. It is not necessary to use a glass material, a metal material or a fluorescent material for the doorway, and other materials may be used depending on the situation.

The dual X-ray source unit 20 is provided in the body unit 10 to emit electrons (E), and the side portion 12 of the body unit 10 is provided in the step 27 provided in the dual X-ray source unit 20. Is inserted and combined. The step 27 provided in the dual X-ray source unit 20 is a focusing body having an outer wall surrounding the outer peripheral surface of the focusing unit 24 and the focusing unit 24 in which the source units 22 and 23 for generating electrons are located. It is formed between 26. Specifically, the outer peripheral surface of the focusing unit 24 is surrounded by an outer wall, and the step 27 is formed at a predetermined interval provided by the focusing unit 24 and the outer wall being spaced apart. At this time, the gap of the step 27 will be preferably made of a width sufficient to correspond to the thickness of the side portion 12 so that the side portion 12 of the body unit 10 can be inserted and coupled.

The anode unit 30 faces the dual X-ray source unit 20 and is located in the body unit 10 to provide X-rays (L) or light (L) generated by collision with the electrons (E) of the body unit (10). It is guided to release to the outside. The anode unit 30 is located at the top of the body unit 10 so as to face the dual X-ray source unit 20.

The light L generated from the anode unit 30 depends on the material of the anode unit 30 and the magnitude of the voltage applied to the dual X-ray source unit 20 and the anode unit 30, X-rays, visible rays, infrared rays, ultraviolet rays It can be either. In this embodiment, it is illustrated that the anode unit 30 is formed of any one of metal made of copper, tungsten, manganese, molybdenum, and combinations thereof to generate X-rays L.

On the other hand, since the body unit 10 combined with the dual X-ray source unit 20 and the anode unit 30 forms an inside in a vacuum atmosphere, a brazing method in which air does not flow into the body unit 10 or It would be a good idea to use adhesive bonding. The brazing method is a method in which brass, lead, silver lead, etc. are used as an adhesive between metal plates to heat and melt them for bonding, and the bonding surface of the body unit 10 and the dual X-ray source unit 20, the body unit 10 and the anode The bonding surfaces of the units 30 may be combined in a brazing manner to secure the bonding between the bonding surfaces.

If the vacuum atmosphere inside the body part can be continuously maintained, various methods and means of bonding may be used in addition to bonding using brazing or adhesive.

3 and 4 show detailed views of the focusing unit on which the CNT and the filament of the dual X-ray source unit according to the present invention are respectively seated.

The dual X-ray source unit 20 emits electrons, and includes a source part 22, 23, a focusing part 24, a focusing body 26, and an electrode part 28. Specifically, at least two installation grooves to be inserted into the source portion 22 and 23 to generate electrons and source portions 22 and 23 in a shape corresponding to the source portions 22 and 23 to be aligned. (243) (244) is provided in different sizes, the focusing unit 24 for focusing the electrons (E) generated from the source unit (22, 23) to the outside, and the outer peripheral surface of the focusing unit (24) Surrounded by, it is located in the focusing body 26 and the installation grooves 243, 244 where a step 27 is formed between the focusing part 24 and the outer wall, and provides a voltage to the source parts 22, 23 It consists of an electrode portion 28 to selectively enable the electron emission of the source portion 22, 23.

The source parts 22 and 23 are settled in the installation grooves 243 and 244 provided in the focusing part 24 to generate electrons, preferably a filament-based thermal electron emission method or a carbon nanotube (CNT). Electrons are generated by at least one of the field emission methods.

The focusing unit 24 is provided with a first inclined surface 241 and a second inclined surface 242, which are connected in a bent shape with the upper surfaces facing each other, and the source parts 22, 23 are provided with installation grooves 243, 244 ), the first installation groove 243 and the second installation groove 244 are formed in the first inclined surface 241 and the second inclined surface 242, respectively.

The first inclined surface 241 and the second inclined surface 242 are formed with a first installation groove 243 and a second installation groove 244 into which the first source portion 22 and the second source portion 23 can be inserted, respectively. do. The first inclined surface 241 and the second inclined surface 242 are first to guide the electrons E emitted from the first source portion 22 and the second source portion 23 toward the anode unit 30 in an inclined manner. The source portion 22 and the second source portion 23 are supported obliquely.

The first installation groove 243 and the second installation groove 244 are formed in a shape corresponding to the first source portion 22 and the second source portion 23, so that the first installation groove 243 and the second installation groove The first source portion 22 and the second source portion 23 are inserted and aligned in the groove 244, respectively.

The first installation groove 243 and the second installation groove 244 have different sizes (a) of the first installation groove 243 and a size (b) of the second installation groove 244. In the present embodiment, the size (a) of the first installation groove 243 is smaller than the size (b) of the second installation groove 244 will be described as an example.

The size (a) of the first installation groove 243 is 0.1 mm or less, and is mainly used when photographing an object having a small or thin thickness, and the size (b) of the second installation groove 244 is 0.3 mm. The above-described formation is used when photographing an object having a thick thickness. That is, since the sizes of the first installation groove 243 and the second installation groove 244 are different, the source parts 22 and 23 aligned with the first installation groove 243 and the second installation groove 244 are also provided. It is made of a corresponding size, and a difference occurs in the focus electrode according to the size of the source parts 22 and 23. Accordingly, the size of the installation grooves 243 and 244 and the source parts 22 and 23 that form the correct focus electrode according to the size and thickness of the object to be inspected may be photographed.

The first installation groove 243 does not necessarily need to be manufactured in a smaller size than the second installation groove 244, and vice versa. However, the smaller installation grooves 243 and 244 are formed to be 0.1 mm or less, and the larger installation grooves 243 and 244 may be manufactured to a size of 0.3 mm or more.

On the other hand, the first source portion 22 and the second source portion 23, which are inserted into the first installation groove 243 and the second installation groove 244 for alignment, can use filaments and carbon nanotubes (CNT). Will be able to. Therefore, one of the filaments and the carbon nanotubes (CNT) is installed in the first installation groove 243 and the second installation groove 244, respectively, and the filament-based thermal electron emission method is provided in one installation groove 243 and 244. Electrons, and emits electrons to the other installation grooves 243 and 244 using a carbon nanotube (CNT)-based field emission method.

The filaments and carbon nanotubes that are the source parts 22 and 23 may be inserted and aligned at any of the first installation groove 243 and the second installation groove 244, and the first installation groove 243 and the second All of the filaments are inserted and aligned in the installation groove 244, so that electrons can be emitted through a filament-based thermal electron emission method. In addition, the carbon nanotubes are inserted and aligned in both the first installation groove 243 and the second installation groove 244, so that electrons may be emitted through a carbon nanotube-based field emission method.

The electrode portion 28 is provided with two electrodes having different polarities in the installation grooves 243 and 244 so as to correspond to the source portions 22 and 23, preferably the first source portion 22 or the second The first electrode portion 28a and the second electrode portion 28b are respectively connected to the first source portion 22 and the second source portion 23 so that the second source portion 23 can emit electrons. Power is provided to the source unit 22 and the second source unit 23.

For example, the first electrode portion 28a passes through the lower end of the focusing portion 24 to provide power to the first source portion 22 inserted and aligned in the first installation groove 243 and the first installation groove 243. The two electrodes having different polarities are disposed. In addition, the first electrode portion 28a is formed with a coupling portion 29 that is detachably coupled to a terminal provided in the first source portion 22. Due to this, when the first source unit 22 has reached the end of its life or has failed, it is possible to replace only the failed first source unit 22 without having to completely replace the dual X-ray source unit 20, thereby saving replacement cost. You will be able to.

That is, at least two electrode portions 28 having different polarities are positioned in one installation groove 243 and 244, and the coupling portion of the electrode portion 28 contacting the source portion 22 and 23 ( 29) is formed in a shape such as a groove or clip formed detachably, so that the terminals of the source portions 22 and 23 can be replaced interchangeably.

In this embodiment, the first source portion 22 and the second source portion 23 are respectively inserted and aligned in the first inclined surface 241 and the second inclined surface 242 formed in the focusing portion 24. Although the parts 22 and 23 are used, in addition to the present embodiment, a plurality of insertion holes may be provided on the inclined surface, and a plurality of source parts 22 and 23 may be inserted and aligned to be used, and a plurality of focusing parts 24 may be used. The inclined surfaces of the dogs may be formed in a bent shape facing each other to insert and align the plurality of source parts 22 and 23.

5 is an exploded perspective view of a focusing unit seated by the CNT of the dual X-ray source unit according to the present invention.

Regarding the source parts 22 and 23 based on carbon nanotubes (CNT), the negative electrode 230 is formed in a thin plate to apply an electrode of the negative electrode, and is stacked on top of the negative electrode 230 to form an electron ( It includes an emitter 231 that emits E) and a thin patterned electrode 233 that is stacked on top of the emitter 231 to extract electrons E from the emitter 231.

The negative electrode 230 is formed of a thin plate-shaped thin plate and is made of a metal material. The negative electrode 230 may be referred to as a cathode electrode as a negative electrode. Since the dual X-ray apparatus 1 operates in a vacuum, an alloy or a single transition metal such as nickel, iron, or cobalt may be used as a material constituting the cathode electrode.

The emitter 231 is an electrode that controls the trajectory of emitted electrons, and is a nano material and includes a conductive material composed of a metal such as carbon nanotubes capable of emitting high current per unit area and a carbon-based material.

The negative electrode 230 and the patterning electrode 233 may be formed in a mesh shape of a metal material, respectively, to guide the emission of electrons E. In the mesh formed on the negative electrode 230 and the patterning electrode 233, a plurality of holes are formed between the metal meshes, and the shape of the holes is formed in a hexagonal shape. As the shape of the hole formed in the mesh is formed in a hexagonal shape, the negative electrode 230 and the patterning electrode 233 efficiently extract electrons (E), while the electrons (E) are not collided by the metal mesh and are discharged stably. This can be maximized.

The shape of the hole formed in the mesh is not necessarily limited to a hexagon, and may be formed in various shapes such as a plurality of circular or square holes.

On the other hand, between the emitter 231 that is the upper portion of the emitter 231 and the patterning electrode 233, an emitter cover 232 through which a cover hole 232a is formed is stacked and electrons emitted from the emitter 231 ( The edge effect of E) is prevented and guided so that the electron E can be uniformly extracted. In addition, between the emitter 231 and the emitter cover 232, a first insulator 234 through which a first insulating hole 234a is formed is stacked, and between the emitter cover 232 and the patterning electrode 233. A second insulator 235 through which the second insulator hole 235a is formed is stacked therein. Therefore, the first insulator 234 and the second insulator 237 are insulated between the emitter 231, the emitter cover 232, and the patterning electrode 233.

In addition, the first support 236 is stacked and supported on the lower portion of the negative electrode 230, and the second support (through which the opening 237a is formed through the second insulator 235 to allow electrons E to be released ( 237) are stacked. Therefore, the lower and upper portions of the source portions 22 and 23 are supported and protected by the first support 236 and the second support 237.

The insulator 234, 237 and the support 236, 237 are both made of a ceramic material, and may be made of an insulating material other than ceramic.

Meanwhile, the negative electrode 230 and the patterning electrode 233 are provided with a negative electrode terminal 230a and a patterning electrode terminal 233a, respectively, and are connected to an external power source. The negative electrode terminal 230a may be connected to the inside of the focusing unit 24 by passing through the first support 236 through an electrode hole formed through the first support 236. In addition, the patterning electrode terminal 233a of the patterning electrode 233 is formed through the second insulator 235, the emitter cover 232, the first insulator 234, and the first support 236 to communicate with each other. It is possible to connect to the inside of the focusing unit 24 through the hole.

As described above, when the negative electrode 230 is applied to the negative electrode 230 supported on the first support 236, the source units 22 and 23 emit electrons E from the emitter 231. The electron E emitted from the emitter 231 is the first insulator hole 234a of the first insulator 234, the cover hole 232a of the emitter cover 232, and the second of the second insulator 235. The insulating hole 235a, the patterning electrode 233, and the opening 237a of the second support 237 are sequentially passed through and discharged.

FIG. 6 is a cross-sectional view of A-A' for the dual X-ray apparatus shown in FIG. 1.

The dual X-ray source unit 20 is provided with at least two source portions 22 and 23, and when a voltage is supplied from the electrode portion 28 to the source portion 22 and 23, the source portion 22 and ( 23) generates electrons. The source parts 22 and 23 are at least one of a heat electron emission method for accelerating heat generated by heating the filament inside the body unit 10 in a vacuum to a high voltage and a carbon nanotube-based field emission. The method of is adopted to emit electrons (E).

The emitted electrons E are directed to the anode unit 30, and the electrons E colliding with the reflective surface 32 of the anode unit 30 are converted into X-rays L or light L, and the body unit ( It passes through the window of 10) and goes outward. At this time, the reflective surface 32 faces the dual X-ray source unit 20, thereby generating X-rays L or light L by collision with the electrons E. In addition, the reflective surface 32 is formed to be inclined toward the window, guiding the X-ray (L) or light (L) to the outside through the window.

When the reflective surface 32 of the anode unit 30 is formed of a material such as glass rather than metal, light L generated by collision with the electrons E may be used as illumination.

Meanwhile, the dual X-ray source unit 20 is provided with at least two source parts 22 and 23, and the source parts 22 and 23 may be used by selecting at least one of filaments or carbon nanotubes. . Preferably, since the sizes of the first installation groove 243 and the second installation groove 244 provided in the focusing portion 24 are different from each other, the source portion 22 is inserted and aligned in the installation grooves 243 and 244 ( The size of 23) will also be different, and the source parts 22 and 23 having different sizes may be selectively used according to the thickness or size of the irradiated object.

That is, in the focusing unit 24, at least one source unit 22, 23 emits electrons, and the emitted electrons are X-rays L or light L converted due to collision with the anode unit 30. It will be directed to the object.

The dual X-ray source unit 20 does not always need to emit electrons from only one source unit 22 and 23, and all source units 22 and 23 provided in the focusing unit 24 according to user convenience ). Alternatively, one or more source units 22 and 23 may be selected according to a user's selection so that electrons can be emitted.

The present invention described above is not limited by the above-described embodiments and accompanying drawings, and various substitutions, modifications, and changes are possible within the scope of the present invention without departing from the technical spirit of the present invention. It will be apparent to those who have the knowledge of.

1: Dual X-ray device 10: Body unit
12: Side 20: Dual X-ray source unit
22: first source section 23: second source section
24: focusing unit 26: focusing body
27: step 28: electrode portion
29: engaging portion 30: anode unit
32: reflective surface

Claims (13)

A source unit that generates electrons;
At least two installation grooves are provided in different sizes to allow the source portion to be inserted and aligned in a shape corresponding to the source portion. A focusing unit for focusing the electrons outside;
A focusing body surrounding the outer peripheral surface of the focusing part with an outer wall; And
An electrode portion positioned in the installation groove and providing voltage to the source portion to enable electron emission of the source portion;
Dual X-ray source unit comprising a. According to claim 1,
The source unit is a dual X-ray source unit for generating the electrons in at least one of a filament-based thermal electron emission method or a carbon nanotube (CNT)-based field emission method. According to claim 1,
The focusing unit,
A first inclined surface and a second inclined surface are provided in which the upper surfaces facing each other are connected in a bent shape, and the first and second inclined surfaces are respectively provided in the first inclined surface and the second inclined surface so that the source part can be inserted into the installation groove. 2 Dual X-ray source unit with installation groove. According to claim 1,
The focusing body,
A dual X-ray source unit in which the outer walls surround and form a spaced apart portion from the focusing portion, and a step is formed in the gap. According to claim 1,
The electrode unit passes through one surface of the focusing unit toward the installation groove so as to correspond to the source unit, and the dual X-ray source unit, characterized in that two electrodes having different polarities are disposed in the installation groove. The method of claim 5,
The electrode portion is a dual X-ray source unit to form a coupling portion detachably coupled to the terminal provided in the source portion to enable the replacement of the source portion. Hollow body unit;
A dual X-ray source unit located on one side of the body unit and emitting electrons; And
An anode unit positioned on the body unit to face the dual X-ray source unit and guiding X-rays or light generated by collision with the electrons to the outside of the body unit;
It includes,
The dual X-ray source unit,
A source unit that generates electrons;
At least two installation grooves are provided in different sizes to allow the source portion to be inserted and aligned in a shape corresponding to the source portion, and generated by selectively using any one of the source portions inserted and aligned in the installation groove. A focusing unit for focusing the electrons outside;
A focusing body surrounding the outer circumferential surface of the focusing portion with an outer wall, and having a step formed at a gap provided by the focusing portion and the outer wall being spaced apart; And
An electrode portion positioned in the installation groove and providing voltage to the source portion to enable electron emission of the source portion;
It includes,
The dual X-ray source unit coupled to the body unit is a dual X-ray device that is inserted into and coupled to a step in which the outer peripheral surface of the body unit is formed in the focusing body. The method of claim 7,
The dual X-ray source unit and the anode unit coupled to the body unit are brazed,
The dual X-ray source unit and the anode unit is combined with the body unit dual X-ray apparatus to form the inside in a vacuum atmosphere. The method of claim 7,
The source unit is a dual X-ray apparatus for generating the electrons in at least one of a filament-based thermal electron emission method and a carbon nanotube (CNT)-based field emission method. The method of claim 7,
The focusing unit,
A first inclined surface and a second inclined surface are provided in which the upper surfaces facing each other are connected in a bent shape, and the first and second inclined surfaces are respectively provided in the first inclined surface and the second inclined surface so that the source part can be inserted into the installation groove. 2 Dual X-ray device where the installation groove is formed. The method of claim 7,
The electrode portion passes through one surface of the focusing portion toward the installation groove so as to correspond to the source portion, the dual X-ray apparatus, characterized in that two electrodes having different polarities are disposed in the installation groove. The method of claim 11,
The electrode unit is a dual X-ray apparatus that allows a replacement portion of the source portion is formed by a coupling portion detachably coupled to the terminal provided in the source portion. The method of claim 7,
The dual X-ray apparatus coupled to the body unit and the bonding surface of the anode unit and the anode unit are combined by a brazing method.

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