KR102369692B1 - Ceramics tube applied at x-ray generator and manufacturing apparatus of thereof - Google Patents

Abstract

A ceramic tube applied to a disclosed X-ray generator, in accordance with comprising a tube body and an active brazing material, enables to directly allow for stratification of a brazing material at an end of the tube body, by directly allowing for stratification of the active brazing material on the end of the tube body made of an alumina ceramic, without the conventional metallizing and nickel plating processes, thereby having an advantage wherein the manufacturing process of the ceramic tube applied to the X-ray generator is simplified.

Description

Ceramic tube applied at x-ray generator and manufacturing apparatus of thereof

The present invention relates to a ceramic tube applied to an X-ray generator and an apparatus for manufacturing the same.

A device for generating X-rays is an X-ray generator. The X-ray generator includes a ceramic tube made of a ceramic insulator and connected to a cathode and an anode for generating X-rays.

What can be presented as an example of a ceramic tube applied to such an X-ray generator is that of the patent literature presented below.

However, the ceramic tube applied to the conventional X-ray generator is made of alumina ceramic, and at least one of a cathode and an anode is connected to the end of the tube body, which becomes a vacuum container in which the electron beam moves, manganese-zinc at the end of the tube body After metallizing the back, nickel was plated thereon, and an aluminum-copper brazing material had to be layered thereon again, thereby complicating the manufacturing process of the ceramic tube.

Patent Publication No. 10-2020-0015003, Publication Date: 2020.02.12., Title of Invention: Method for surface modification of ceramic insulating tube of X-ray tube

An object of the present invention is to provide a ceramic tube applied to an X-ray generator capable of directly layering a brazing material on the end of a tube body without a metallizing and nickel plating process, and an apparatus for manufacturing the same.

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An apparatus for manufacturing a ceramic tube applied to an X-ray generator according to an aspect of the present invention is for manufacturing a ceramic tube applied to an X-ray generator,

A vacuum member for forming a vacuum atmosphere so that an active brazing material is directly layered on the end surface of the tube body so that the end of the tube body, which is made of alumina ceramic and becomes a vacuum container in which the electron beam moves, is connected to at least one of a cathode and an anode; and a floor shock buffer member capable of buffering a floor impact transmitted from the installation surface of the vacuum member to the vacuum member;

The bottom shock-absorbing member includes a buffer body extending downwardly from the bottom surface of the vacuum member, an external guide extending downward along the outer periphery of the buffer body in a cylindrical shape, and in close contact with the inner surface of the external guide body A tapered elevating body that can be lifted from the inside of the external guide, the upper surface of which is formed in a tapered shape that becomes relatively higher toward the center thereof, and a vertical lifting hole recessed to a predetermined depth from the upper surface of the central portion of the tapered elevating body; , a vertical riser that can be lifted along the vertical ascending hole, which can be inserted into the vertical ascending hole or protrude to the outside of the vertical ascending hole, and a panel shape to partition the inside of the external guide in a horizontal direction Is formed, the bottom surface of the central portion of the tapered elevating member and the support panel to be crushed supported in contact with the vertical riser, and extending downward to a predetermined length so as to be spaced apart from each other from the buffer body, the upper surface of the support panel to be crushed A pair of eccentric pressure pillars each eccentrically press the symmetrical points eccentric so as to be spaced apart from the central part of the An air compression buffer hole that is depressed to a predetermined diameter and then expanded to a relatively larger diameter inside the buffer body, and a portion of the air compression buffer hole that is depressed to a predetermined diameter along the central portion of the downward protruding stopper The pressurized lifting body that can be lifted and lowered accordingly, and the outer surface of the air compression buffer hole is inserted so as to be close to the inner surface of the portion formed in a relatively larger diameter expanded form inside the buffer body, the air compression A pressurized lifting panel that can be lifted along a portion formed in an expanded form to a relatively larger diameter in the cushioning hole of the cushioning body, and is connected to the upper portion of the pressurized lifting body to be lifted together; An elastic material installed in a pair so as to be symmetrical to each other on the inclined upper surface of the tapered elevator is made of, air is accommodated therein, the support panel to be crushed is non-contact with the support panel to be crushed while the panel shape is maintained, and the support panel to be crushed when the support panel to be crushed is crushed and lowered The pressurized elastic air receptor, which is pressed by the , so that the air therein is discharged, and the pressurized elastic air receptor and the lower part of the vertical rising hole are communicated to communicate the air discharged after being inside the pressurized elastic air receptor and an air flow pipe that flows and flows into the lower portion of the vertical riser so that the vertical riser can be raised,

While the support panel to be crushed maintains the panel shape, the vertical riser maintains a state inserted into the vertical lift hole, and the central portion of the tapered lifter and the vertical riser are the bottom surface of the support panel to be crushed In contact with the central portion of the, the pressurized elastic air receptor is non-contact with the support panel to be crushed, and each of the eccentric pressure columns is eccentric at a predetermined distance from the central portion of the upper surface of the support panel to be crushed While pressing each part, the buffer Supporting the body, the pressurized rising panel is in contact with the bottom surface of the air compression buffer hole, the pressurized rising body is lowered so that the lower part of the pressurized rising body protrudes to the outside of the downward protruding stopper, the crushed support panel maintain a non-contact state with the upper surface of

When the taper elevating body is raised inside the external guide body by the bottom impact transmitted from the installation surface of the vacuum member to the vacuum member, the crushable support panel is crushed by being pressed by the tapered elevating member, As each crushed part of the crushing support panel is lowered, the pressurized elastic air receptor is pressed, and as the pressurized elastic air receptor is elastically deformed, the air inside the pressurized elastic air receptor is discharged and the air flow pipe is After flowing through the vertical ascending body, it flows into the lower portion of the vertical ascending hole, and accordingly, the vertical ascending body is raised by the pressure of the air introduced into the vertical ascending hole and protrudes to the outside of the central portion of the tapered ascending body to press the pressurized ascending object. As the pressurized rising body and the pressurized rising panel are raised together, the air in the air compression buffer hole is compressed by the pressurized rising panel to cushion the floor impact.

According to the ceramic tube applied to the X-ray generator and the apparatus for manufacturing the same according to an aspect of the present invention, as the ceramic tube applied to the X-ray generator includes a tube body and an active brazing material, the tube body made of alumina ceramic By directly layering the active brazing material at the end, it is possible to directly layer the brazing material on the end of the tube body without a conventional metallizing and nickel plating process, and accordingly, the manufacturing process of the ceramic tube applied to the X-ray generator is simplified It has a destructive effect.

1 is a view showing a ceramic tube applied to an X-ray generator according to an embodiment of the present invention.
2 is a view showing the configuration of an apparatus for manufacturing a ceramic tube applied to an X-ray generator according to an embodiment of the present invention.
3 is an enlarged view of a part of a vacuum member constituting an apparatus for manufacturing a ceramic tube applied to an X-ray generator according to an embodiment of the present invention;

Hereinafter, a ceramic tube applied to an X-ray generator according to an embodiment of the present invention and an apparatus for manufacturing the same will be described with reference to the drawings.

1 is a view showing a ceramic tube applied to an X-ray generator according to an embodiment of the present invention, and FIG. 2 is a view showing the configuration of an apparatus for manufacturing a ceramic tube applied to an X-ray generator according to an embodiment of the present invention. , FIG. 3 is an enlarged view of a part of a vacuum member constituting an apparatus for manufacturing a ceramic tube applied to an X-ray generator according to an embodiment of the present invention.

1 to 3 , the ceramic tube 100 applied to the X-ray generator according to the present embodiment is applied to the X-ray generator, and includes a tube body 110 and an active brazing material 120 .

The tube body 110 is made of alumina ceramic and is a vacuum container in which an electron beam moves, and the tube body 110 may have an empty circular cylinder shape.

The active brazing material 120 is applied to the distal end of the tube body 110 so that at least one of the cathode and the anode and the end of the tube body 110 are connected, and on the end surface of the tube body 110 . It is directly layered and layered.

In this embodiment, the active brazing material 120 may be presented as a titanium-aluminum-copper alloy.

As described above, as the ceramic tube 100 applied to the X-ray generator includes the tube body 110 and the active brazing material 120, at the end of the tube body 110 made of alumina ceramic, the Since the active brazing material 120 is directly layered, it is possible to directly layer the brazing material on the end of the tube body 110 without a conventional metallizing and nickel plating process, and accordingly, the ceramic tube applied to the X-ray generator The manufacturing process of (100) becomes simple.

On the other hand, the apparatus 150 for manufacturing a ceramic tube applied to the X-ray generator according to the present embodiment is for manufacturing the ceramic tube 100 applied to the X-ray generator, and includes a vacuum member 160 and a bottom shock-absorbing member ( 170).

The vacuum member 160 is made of alumina ceramic and is attached to the end surface of the tube body 110 so that the end of the tube body 110, which is a vacuum container in which the electron beam moves, is connected to at least one of a cathode and an anode. By forming a vacuum atmosphere so that the active brazing material 120 is directly layered, a closed room in which the inside is blocked from the outside may be presented as an example.

Reference numeral 165 denotes a vacuum pump capable of applying a vacuum to the inside of the vacuum member 160 .

The bottom shock buffer member 170 is capable of buffering the floor impact transmitted from the installation surface (bottom surface) of the vacuum member 160 to the vacuum member 160 , the buffer body 171 and the external guide A sieve 172, a tapered elevating body 173, a vertical rising hole 174, a vertical rising body 175, a crushable support panel 176, a pair of eccentric pressure columns 177, The downward protruding stopper 178 , the air compression buffer hole 180 , the pressurized rising body 179 , the pressurized rising panel 181 , the pressurized elastic air receiver 182 , and the air flow pipe 183 . includes

The buffer body 171 is to extend downward from the bottom surface of the vacuum member (160).

The external guide 172 extends downward along the outer edge of the buffer body 171 in a cylindrical shape, and the inside of the external guide 172 is empty so that the tapered elevator 173 can be raised formed in the form

The tapered elevating body 173 can be lifted from the inside of the external guide 172 in a state of being in close contact with the inner surface of the external guide 172, and the upper surface of the external guide 172 is in a tapered shape that is relatively higher toward the center. will be formed

The external guide body 172 is formed in a tube shape, and the tapered elevating body 173 is formed in a cylindrical shape that can be in close contact with the inner surface of the external guide 172 as a whole, and the tapered elevating body 173 . The upper surface of the cap protrudes in a tapered shape in the shape of a hat.

The vertical lifting hole 174 is vertically depressed to a predetermined depth from the upper surface of the central portion of the tapered lifting body 173 .

The vertical rising body 175 may be lifted along the vertical rising hole 174 , such that it may be inserted into the vertical rising hole 174 or may protrude out of the vertical rising hole 174 .

The support panel 176 to be crushed is formed in a panel shape to partition the inside of the external guide body 172 in the horizontal direction, and the lower surface of the central part of the support panel 176 to be crushed is the tapered elevating body 173 . It is supported in contact with the central portion and the vertical riser 175 of the.

The support panel 176 to be crushed is formed in the form of a flat circular panel inserted into the inside of the external guide 172, and before the support panel 176 to be crushed is crushed by the floor impact, its original shape During maintenance, the lower surface of the central portion of the support panel 176 to be crushed is supported by the central portion of the tapered elevating body 173 and the vertical riser 175, and the central portion of the support panel 176 to be crushed Two points symmetrical to each other among the edge portions spaced apart from the upper surface by a predetermined distance are pressed by the respective eccentric pressure pillars 177 .

Each of the eccentric pressure pillars 177 extend downwardly from the buffer body 171 by a predetermined length, are formed to be spaced apart from each other, and symmetrical points eccentric to be spaced apart from the central portion of the upper surface of the crushable support panel 176 by a predetermined distance. are pressed eccentrically to each.

When each of the eccentric pressure pillars 177 maintains a state of pressing each portion of the support panel 176 to be crushed, the central portion of the tapered elevating body 173 and the vertical elevating body 175 support Each of the eccentric pressure pillars 177 are placed on the support panel 176 in a state to be crushed, and accordingly, the buffer body 171 and the vacuum member 160 are also the support panel 176 to be crushed. will remain supported by

The downward protrusion stopper 178 is to protrude downward from the center of the bottom surface of the buffer body 171 .

The air compression buffer hole 180 is vertically depressed upward with a predetermined diameter along the central portion of the downward protruding stopper 178, and is formed in a form that is expanded to a relatively larger diameter inside the buffer body 171 As such, it is formed in a T-shaped cross section.

The pressurized lifting body 179 may be raised and lowered along a portion recessed to a predetermined diameter along the central portion of the downward protruding stopper 178 among the air compression buffer holes 180 .

While the support panel 176 to be crushed before being crushed by the floor impact and maintaining its original shape, each of the eccentric pressure posts 177 is in contact with each part of the support panel 176 to be crushed, The downward protruding stopper 178 and the pressurized riser 179 remain above the crushed support panel 176 to maintain a non-contact state with the crushed support panel 176 .

The pressurized rising panel 181 is inserted so that the outer surface of the air compression buffer hole 180 is closely attached to the inner surface of the portion formed in a relatively larger diameter expanded shape inside the buffer body 171 , , can be lifted along a portion of the air compression buffer hole 180 formed in a relatively larger diameter expanded form inside the buffer body 171 , and connected to the upper portion of the pressurized body 179 . and can be lifted together.

When the pressurized rising panel 181 rises, the air in the air compression buffer hole 180 is compressed.

The pressurized lifting body 179 may be raised and lowered along the leg portion of the T-shaped cross section of the air compression buffer hole 180 , and relatively among the T-shaped cross-sections of the air compression buffer hole 180 . The pressurized lifting panel 181 may be raised and lowered along the wide head.

The pressurized elastic air receiver 182 is installed in a pair so as to be symmetrical to each other on the inclined upper surface of the tapered elevating body 173, is made of an elastic material such as rubber, and air is accommodated therein, While the support panel 176 to be crushed maintains the panel shape, it is not in contact with the support panel 176 to be crushed, and when the support panel 176 to be crushed is crushed and lowered to the support panel 176 to be crushed. It is pressed by the pressure so that the air inside it is discharged.

While the support panel 176 to be crushed maintains the panel shape, the inside of the pressurized elastic air receptor 182 is filled with air so that the pressurized elastic air receptor 182 maintains the inflated shape, When the crushed support panel 176 is crushed and lowered, the pressurized elastic air receptor 182 is pressed and elastically deformed by the crushed and descending fragments of the crushed supporting panel 176, and accordingly, the pressured The air in the interior of the elastic air receptor 182 is discharged.

For example, when the floor impact is applied, the tapered lifting member 173 rises and impacts the lower surface of the central portion of the support panel 176 to be crushed, thereby being crushed from the center of the support panel 176 to be crushed. The support panel 176 to be crushed is broken in the form of two halves, and accordingly, each broken fragment of the support panel 176 to be crushed presses the respective pressurized elastic air receivers 182 .

The air flow pipe 183 communicates the pressurized elastic air receptor 182 and the lower portion of the vertical rising hole 174, so that the air discharged after being in the pressurized elastic air receptor 182 flows. By flowing into the lower portion of the vertical rising hole 174, the vertical rising body 175 can be raised by the pressure of the air transferred from the pressurized elastic air receiver 182 .

When configured as described above, while the support panel 176 to be crushed maintains the panel shape, the vertical riser 175 maintains a state inserted into the vertical riser hole 174, and the taper rises and falls. The central portion of the sieve 173 and the vertical riser 175 are in contact with the central portion of the bottom surface of the support panel 176 to be crushed, and the pressurized elastic air receiver 182 is non-contact with the support panel 176 to be crushed. and each eccentric pressure column 177 supports the cushioning body 171 while pressing each part eccentric at a predetermined distance from the central portion of the upper surface of the crushed support panel 176, and the pressurized rising panel 181 is in contact with the bottom surface of the air compression buffer hole 180, the pressurized lifting body 179 so that the lower portion of the pressurized lifting body 179 protrudes to the outside of the downward protruding stopper 178 is It is lowered and maintains a non-contact state with the upper surface of the support panel 176 to be crushed.

On the other hand, when the taper elevating body 173 is raised inside the external guide body 172 by the bottom impact transmitted from the installation surface of the vacuum member 160 to the vacuum member 160, the crushed object The support panel 176 is crushed by being pressed by the tapered lifting member 173, and as each crushed part of the support panel 176 to be crushed is lowered, the pressurized elastic air receiver 182 is pressed. As the pressurized elastic air receiver 182 is elastically deformed, the air inside the pressurized elastic air receiver 182 flows out and flows through the air flow pipe 183 to the lower portion of the vertical rising hole 174 . The vertical elevation body 175 is raised by the pressure of the air introduced into the vertical elevation hole 174 and protrudes to the outside of the central portion of the tapered elevation body 173 by the pressure of the air introduced into the vertical elevation hole 174. 179) is pressed, and the pressurized rising body 179 and the pressurized rising panel 181 are raised together, so that the air in the air compression buffer hole 180 is moved to the pressurized rising panel 181. It is compressed by the cushioning the floor impact.

At this time, when the vertical riser 175 raised through the crushed portion of the support panel 176 to be crushed comes into contact with the downward protrusion stopper 178, the vertical riser 175 stops rising. do.

In the above, the present invention has been shown and described with respect to specific embodiments, but those skilled in the art can variously modify the present invention within the scope without departing from the spirit and scope of the present invention as set forth in the claims below. and may be changed. However, it is intended to clearly state that all such modifications and variations are included within the scope of the present invention.

According to the ceramic tube and its manufacturing apparatus applied to the X-ray generator according to an aspect of the present invention, the brazing material can be directly layered on the end of the tube body without metallizing and nickel plating processes, so the industrial applicability is high. .

100: ceramic tube applied to the X-ray generator
110: tube body
120: active brazing material

Claims (3)

delete delete For manufacturing a ceramic tube applied to an X-ray generator,
A vacuum member for forming a vacuum atmosphere so that an active brazing material is directly layered on the end surface of the tube body so that the end of the tube body, which is made of alumina ceramic and becomes a vacuum container in which the electron beam moves, is connected to at least one of a cathode and an anode; and
Including; and a bottom shock buffer member capable of buffering the floor impact transmitted to the vacuum member from the installation surface of the vacuum member;
The floor shock-absorbing member is
A buffer body extending downwardly from the bottom surface of the vacuum member;
an external guide body extending downwardly along the outer periphery of the buffer body in a cylindrical shape;
a tapered elevating body that can be lifted from the inside of the external guide in a state of being in close contact with the inner surface of the external guide, the upper surface of which is formed in a tapered shape that is relatively higher toward the center thereof;
a vertical lifting hole recessed to a predetermined depth from the upper surface of the central portion of the tapered lifting body;
a vertical rising body that can be lifted along the vertical rising hole, and which can be inserted into the vertical rising hole or protrude to the outside of the vertical rising hole;
A support panel to be crushed is formed in the form of a panel to partition the inside of the external guide in the horizontal direction, and the bottom surface of the central part is supported in contact with the central part of the tapered elevating body and the vertical elevating body;
A pair of eccentric pressure pillars extending downward to a predetermined length so as to be spaced apart from each other from the cushioning body to eccentrically press the eccentric symmetrical points to be spaced apart from each other by a predetermined distance from the central portion of the upper surface of the support panel to be crushed;
And a downwardly protruding stopper that protrudes downwardly from the center of the bottom surface of the cushioning body;
An air compression buffer hole that is depressed to a predetermined diameter along the central portion of the downward protruding stopper and is expanded to a relatively larger diameter inside the buffer body;
a pressurized riser capable of being raised and lowered along a portion recessed to a predetermined diameter along the central portion of the downward protruding stopper among the air compression buffer holes;
Inserted so that the outer surface of the air compression buffer hole is close to the inner surface of the portion formed in a relatively larger diameter expanded form inside the buffer body, relatively inside the buffer body of the air compression buffer hole A pressurized lifting panel that can be lifted along a portion formed in an expanded form to a larger diameter and can be raised and lowered together by being connected to an upper portion of the pressurized lifting body;
Installed in a pair so as to be symmetrical to each other on the inclined upper surface of the tapered elevator body, made of an elastic material, air is accommodated therein, and while the supporting panel to be crushed maintains the panel shape, the crushed target a pressurized elastic air receiver which is not in contact with the support panel and is pressed by the support panel to be crushed when the support panel to be crushed and is lowered so that the air therein is discharged;
By communicating the pressurized elastic air receptor and the lower part of the vertical rising hole, the air discharged from the inside of the pressurized elastic air receptor flows and flows into the lower part of the vertical rising hole so that the vertical rising body can be raised. comprising an air flow tube;
While the support panel to be crushed maintains the panel shape, the vertical riser maintains a state inserted into the vertical ascending hole, and the central portion of the tapered lifter and the vertical riser are the bottom surface of the support panel to be crushed In contact with the central portion of the, the pressurized elastic air receptor is not in contact with the crushed support panel, and each of the eccentric pressure pillars is eccentric at a predetermined distance from the central portion of the upper surface of the crushed support panel while pressing each part while pressing the buffer Supporting a body, the pressurized lifting panel is in contact with the bottom surface of the air compression buffer hole, the pressurized lifting body is lowered so that the lower portion of the pressurized ascending body protrudes to the outside of the downward protruding stopper, the crushed support panel maintain a non-contact state with the upper surface of
When the taper elevating member is raised inside the external guide body by the floor impact transmitted from the installation surface of the vacuum member to the vacuum member, the crushable support panel is crushed by being pressed by the tapered elevating member, As each crushed portion of the crushing support panel is lowered, the pressurized elastic air receptor is pressed, and as the pressurized elastic air receptor is elastically deformed, the air inside the pressurized elastic air receptor is discharged and the air flow pipe is After flowing through the vertical ascending body, it flows into the lower portion of the vertical ascending hole, and accordingly, the vertical ascending body is raised by the pressure of the air introduced into the vertical ascending hole and protrudes to the outside of the central portion of the tapered lifting body to press the pressurized ascending object. X-ray generator, characterized in that, as the pressurized lifting body and the pressurized ascending panel are raised together, the air in the air compression buffer hole is compressed by the pressurized ascending panel to cushion the floor impact. Applied to the manufacturing apparatus of the ceramic tube.

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