KR102451350B1 - Method and apparatus for making portable x-ray scanning device with high bubble removal performance - Google Patents

Abstract

A method for manufacturing a portable X-ray imaging device with high bubble removal performance according to the present invention includes the steps of: heating and flowing insulating oil; discharging the heated insulating oil in a gravitational direction from the inside of a first accommodating container, and flowing the heated insulating oil while applying vibration thereto; flowing the insulating oil discharged into the first accommodating container into a second accommodating container; applying negative pressure to the second accommodating container containing the insulating oil, to remove air therefrom; flowing the insulating oil in the second accommodating container to accommodate the insulating oil in an accommodating housing, and disposing a casing to be filled with insulating oil inside the accommodating housing; moving the accommodating housing in which the casing is disposed; and applying negative pressure to the inside of the accommodating housing.

Description

Manufacturing method and manufacturing apparatus of portable X-ray imaging device with high bubble removal performance

The present invention relates to a method and manufacturing apparatus for a portable X-ray imaging device having high bubble removal performance, and more particularly, to effectively remove air bubbles from insulating oil injected into an X-ray imaging device to increase insulation performance and to increase the filling efficiency of insulating oil The present invention relates to a method and apparatus for manufacturing a portable X-ray imaging device having high bubble removal performance, which are configured to

An X-ray imaging device shows the difference in absorption rates of various organs inside the human body as an image by using X-rays whose absorption varies depending on the material.

These X-ray imaging devices are being used for physical diagnosis of humans and animals, as well as for non-destructive testing that reveals defects inside structures.

Conventionally, most of the X-ray imaging devices used for medical purposes are large and heavy, so they are installed and used in medical institutions.

Alternatively, since it is necessary to use an X-ray imaging device mounted on a vehicle during an external business trip to a medical institution, it is difficult to use the X-ray imaging device for patients with reduced mobility.

In order to solve the above problems, small portable X-ray imaging devices have recently been developed.

The X-ray imaging device transmits X-rays generated from an X-ray tube to a patient or an animal, and the like, and the X-ray tube has a cathode terminal and an anode terminal, and the hot electrons emitted from the cathode terminal are strongly applied to the anode terminal. collide to generate X-rays.

In order to strongly collide the hot electrons emitted from the cathode terminal on the anode terminal, a high voltage must be applied between the anode terminal and the cathode terminal. are placed

The power conversion circuit includes various magnetic cores, a low voltage/high voltage bobbin surrounding the magnetic core, and a rectifier for rectifying an induced high voltage.

A lot of heat is generated from the power conversion circuit and the X-ray tube as described above, and in order to prevent high voltage discharge due to high voltage applied to various circuit elements, insulating oil for insulating the circuit elements is filled inside the X-ray imaging device. do.

However, since various circuit elements such as a high-voltage transformer disposed inside the photographing device are arranged very densely, a space in which insulating oil cannot be filled may be generated due to the surface tension of various terminal parts and circuit elements.

In particular, when fine air bubbles (bubbles) are present in the insulating oil, the possibility that a space in which the insulating oil cannot be finely filled is generated in the circuit elements is further increased.

In addition, when the photographing device becomes more compact and the performance is improved, and various circuit elements disposed therein are also complicated with high spatial density, the high voltage precision also increases, and the air bubbles of the insulating oil filled inside the photographing device are the cause of the high voltage discharge. this can be

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and apparatus for manufacturing a portable X-ray imaging device having high bubble removal performance, which is configured to completely remove bubbles from insulating oil filled in the portable X-ray imaging device.

Another object of the present invention is to provide a method and apparatus for manufacturing a portable X-ray imaging device having high bubble removal performance, which is configured to rapidly remove bubbles from the insulating oil while increasing the filling efficiency of the insulating oil into the imaging device.

A method for manufacturing a portable X-ray imaging device having high bubble removal performance according to the present invention for achieving the above object includes the steps of heating and flowing insulating oil, and discharging the heated insulating oil in the direction of gravity from the inside of the first container while applying vibrations. The step of flowing, the step of flowing the insulating oil discharged into the first accommodating container into a second accommodating container, and applying a pressure to the second accommodating container in which the insulating oil is accommodated to remove air; The steps of flowing the insulating oil in the container to accommodate it inside the housing housing and arranging a casing to be filled with insulating oil inside the housing housing, flowing the housing housing in which the casing is disposed, and applying a negative pressure to the interior of the housing housing includes steps.

Preferably, a nozzle for injection is installed at the upper end inside the first accommodating container, and the heated insulating oil is discharged through the nozzle for injection.

In addition, an insulating fluid member may be installed inside the first accommodating container.

Here, the insulating fluid member may be formed of a stainless steel material, and a plurality of openings may be formed therein.

In addition, lattice-shaped recesses may be formed on the surface of the insulating fluid member.

Preferably, the insulating fluid member is heated while vibrating.

And, it may be configured to remove the air inside the insulating oil sprayed by applying an up pressure to the first accommodating container.

On the other hand, a heating means for heating the insulating oil accommodated in the second container may be installed.

Here, an adsorption member for adsorbing the insulating oil accommodated in the second container may be disposed.

In addition, a vibration generating member for applying vibration to the adsorption member may be disposed inside the second accommodating container.

On the other hand, the apparatus for manufacturing a portable X-ray imaging device having high bubble removal performance according to the present invention includes a heating device member for heating insulating oil to flow while heating, and a first for removing air in insulating oil discharged while discharging the heated insulating oil in the direction of gravity. An air removing member, a second air removing member for removing air bubbles by applying a pressure while receiving the insulating oil, and an insulating oil injection member for accommodating the insulating oil and the insulating oil filling target casing therein and injecting the insulating oil into the casing and a negative pressure applying part is installed in the housing housing of the insulating oil injection member, the housing housing is configured to reciprocate about an axis, and a nozzle for injection is installed at the upper end of the first air removal member inside the first air removing member, heated insulating oil is sprayed and discharged through the nozzle for injection, and an insulating oil flow member for flowing the insulating oil sprayed along the surface is installed inside the first air removal member, and the insulating fluid member is formed of a stainless steel material, and inside A plurality of openings are formed, and the insulating fluid member is configured to vibrate while being heated.

Preferably, lattice-shaped recesses are formed on the surface of the insulating fluid member.

Here, it may be configured to remove the air inside the insulating oil sprayed by applying an up pressure to the first air removing member.

In addition, a heating means for heating the insulating oil accommodated in the second air removal member may be installed.

In addition, an adsorption member for adsorbing the received insulating oil may be disposed inside the second air removing member.

Meanwhile, a vibration generating member for applying vibration to the adsorption member may be disposed inside the second air removing member.

According to the present invention, it is possible to completely remove air bubbles from the insulating oil filled in the portable X-ray imaging device, thereby promoting the miniaturization of the device and the advancement of performance.

In addition, while rapidly removing air bubbles from the insulating oil, it is possible to increase the efficiency of filling the insulating oil into the photographing device, thereby increasing the manufacturing yield of the photographing device.

The accompanying drawings are for understanding the technical spirit of the present invention together with the detailed description of the present invention, so the present invention should not be construed as limited to the matters shown in the following drawings.
1 is a block diagram of an apparatus for manufacturing a portable X-ray imaging device having high bubble removal performance according to the present invention;
2 is a perspective view of a first air removal member included in the manufacturing apparatus;
3 is a perspective view of an insulating fluid member included in the first air removal member;
4 is a perspective view of a second air removal member included in the manufacturing apparatus;
5 is a perspective view of the second air removal member according to another embodiment of the present invention;
6 is a perspective view of a heating means, an adsorption member, and a vibration generating member included in the second air removing member;
7 is a perspective view of a portable X-ray imaging device according to an embodiment of the present invention;
8 is a perspective view of an insulating oil injection member included in the manufacturing apparatus;
9 is a flowchart of a method for manufacturing a portable X-ray imaging device having high bubble removal performance according to the present invention.

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

Prior to this, the terms used in the present specification and claims should not be construed as being limited in the dictionary meaning, and based on the principle that the inventor can appropriately define the concept of the term to describe his invention in the best way. , should be interpreted as meanings and concepts consistent with the technical spirit of the present invention.

Accordingly, the configurations shown in the embodiments and drawings described in the present specification are only preferred embodiments of the present invention, and do not express all the technical ideas of the present invention, so various equivalents that can be substituted for them at the time of the present application It should be understood that water and variations may exist.

1 is a block diagram of a portable X-ray imaging device manufacturing apparatus according to the present invention, FIG. 2 is a perspective view of a first air removing member included in the manufacturing apparatus, and FIG. 3 is an insulating oil included in the first air removing member. A perspective view of a flow member, FIG. 4 is a perspective view of a second air removing member included in the manufacturing apparatus, FIG. 5 is a perspective view of the second air removing member according to another embodiment of the present invention, and FIG. 2 is a perspective view of a heating means, an adsorption member, and a vibration generating member included in the air removal member, FIG. 7 is a perspective view of a portable X-ray imaging device according to an embodiment of the present invention, and FIG. 8 is an insulating oil included in the manufacturing device. It is a perspective view of an injection member, and FIG. 9 is a flowchart of a method for manufacturing a portable X-ray imaging device according to the present invention.

1 and 7, the portable X-ray imaging device 60 manufacturing apparatus according to the present invention includes a heating device member 10 for flowing insulating oil while heating, and the insulating oil discharged while discharging the heated insulating oil in the direction of gravity. A first air removing member 20 for removing air, a second air removing member 30 for removing air bubbles by applying an up pressure while accommodating insulating oil, and a casing 63 filled with insulating oil and insulating oil therein and an insulating oil injection member 50 for receiving and injecting insulating oil into the casing 63, and a negative pressure applying unit 56 is installed in the receiving housing 52 of the insulating oil injection member 50, and the receiving The housing 52 is configured to reciprocate about an axis 54 .

An embodiment of the portable X-ray imaging device 60 according to the present invention is, for example, as shown in FIG. 7 , a casing 63 and an X-ray tube 68 and various circuit elements accommodated in the casing 63 . (62) and a step-up transformer (66) and the like.

The configuration of the various circuit elements 62 and the boosting transformer 66 accommodated in the casing 63 may be variously modified.

In a state in which the various circuit elements 62 and the boosting transformer 66 are disposed inside the casing 63, insulating oil is filled through the opening 61 of the casing and a stopper is coupled thereto.

As shown in FIG. 1 , the apparatus for manufacturing a portable X-ray imaging device according to the present invention includes a heating device member 10 for heating and flowing insulating oil to be filled in the casing 63 .

The heating device member 10 is configured to include a heating coil part 12 to heat insulating oil, and heats the insulating oil to a predetermined temperature and flows it toward the first air removal member 20 .

By heating the insulating oil through the heating device member 10 as described above, air particles present in the insulating oil actively flow.

In this state, the heated insulating oil flowing toward the first air removing member 20 is discharged downward from the inside of the first air removing member 20 .

As shown in FIG. 2 , the first air removal member 20 includes a first accommodating container 21 having a cylindrical shape, and heated insulating oil is applied to the upper end of the first accommodating container 21 . A nozzle 22 for spraying into the receiving container 21 is installed.

The nozzle 22 for injection sprays the heated insulating oil into the first accommodating container 21 in a spraying manner, whereby the heated insulating oil may be sprayed in the form of fine droplets.

Thus, it is in a more favorable state for the air particles present in the insulating oil to evaporate and scatter.

An insulating oil flow member 24 for flowing the insulating oil sprayed as described above downward along the surface may be installed inside the first air removing member 20 .

The insulating fluid member 24 is made of a stainless steel material and is formed in a cylindrical shape as a whole, and an inner panel 241 for flowing the injected insulating oil to the insulating fluid member 24 is disposed therein.

A flow groove is formed on the surface of the inner panel 241 , and the insulating oil dropped onto the inner panel 241 flows to the insulating oil flow member 24 along the flow groove.

The insulating fluid member 24 may have a plurality of small openings 242 formed therein so that the surface area thereof can be increased as much as possible.

Thus, the insulating oil sprayed in the form of fine droplets in a heated state flows through the surface of the insulating oil flow member 24 so that the surface area is maximized.

In addition, a vibration generating member 27 for applying vibration is installed in the insulating oil flow member 24 .

In this state, it is configured to apply vibration while the insulating oil flows through the insulating fluid flow member 24 .

Accordingly, air particles present in the heated insulating oil can be effectively discharged into the inner space of the first air removing member 20 .

On the other hand, the first air removing member (20) is provided with a negative pressure applying unit (28) for applying a negative pressure to the inside of the first receiving container (21).

And, by applying a negative pressure through the negative pressure applying unit 28, it is configured to suck the air leaked into the first air removing member (20).

With this configuration, it is possible to remove air particles present in the insulating oil.

In addition, a heating unit 26 may be installed in the insulating fluid member 24 .

Thus, the air is heated and evaporated in the process in which the injected insulating oil flows through the surface of the insulating oil flow member 24 .

In another embodiment of the present invention shown in Fig. 3, in order to further increase the surface area of the insulating fluid member 24, lattice-shaped recesses 244 may be formed on the surface of the insulating fluid member 24. have.

Thus, by increasing the path through which the injected insulating oil flows along the surface of the insulating fluid flow member 24, it is configured to further increase the evaporative scattering efficiency of air.

The insulating oil from which air particles are removed through the first air removing member 20 flows to the second air removing member 30 by opening the valve 29 .

The second air removing member 30 includes a second accommodating container 31 having a cylindrical shape, and the insulating oil flowing into the second air removing member 30 is accommodated in the second accommodating container 31 . is cooled

A negative pressure applying unit 32 for applying a negative pressure to the inside of the second accommodating container 31 is also installed in the second air removing member 30 to apply a negative pressure through the negative pressure applying unit 32 during cooling of the insulating oil. configured to do

Thus, the second air removing member 30 is configured to suction and remove air particles scattered during the fall of the insulating oil through the negative pressure applying unit 32 .

In another embodiment of the present invention shown in FIGS. 5 and 6 , an adsorption member 36 for adsorbing insulating oil may be disposed inside the second air removing member.

The adsorption member 36 is formed of a porous material such as a sponge or nonwoven fabric, and the insulating oil flows through the adsorption member 36 to increase the surface area.

In addition, a vibration generating member 38 for applying vibration is coupled to the suction member 36 , and is configured to apply vibration to the suction member 36 .

Thus, by vibration applied while the insulating oil flows through the adsorption member 36 , air particles remaining in the insulating oil are scattering into the second accommodating container 31 .

In addition, a heating means 34 for heating the insulating oil may be installed under the adsorption member 36 inside the second air removal member 30 .

The heating means (34) includes a circular heating plate (34) for heating the insulating oil flowing through the adsorption member (36).

The insulating oil in a state in which air bubbles are removed by the second air removing member 30 flows to the insulating oil injection member 50 by opening the valve 39 .

As shown in FIG. 8 , the insulating oil injection member 50 includes a hexahedral accommodating housing 52 , and the insulating oil with the insulating oil in a state in which air bubbles are removed as described above in the accommodating housing 52 . A casing 61 for filling the

The receiving housing 52 of the insulating oil injection member 50 is configured to reciprocate about a shaft 54, and a negative pressure applying unit 56 for applying a negative pressure to the inside of the receiving housing 52 is installed on one side. do.

In addition, a pressure sensor unit 57 for sensing the pressure inside the accommodation housing 52 is installed in the accommodation housing 52 .

In this state, by flowing the accommodation housing 52 in a reciprocating motion method, the insulating oil is filled into the casing 61 .

By filling the insulating oil while flowing the casing 61 as described above, the insulating oil can flow to a corner inside the casing 61 .

And, in this process, air from the inner space of the casing 61 generated due to the filling of the insulating oil may be sucked and removed through the negative pressure applying unit 56 .

Thus, the filling speed of the insulating oil can be increased by sucking and removing the air present in the corner inside the casing 61 through the negative pressure applying unit 56 .

Meanwhile, referring to FIG. 9 , the method for manufacturing a portable X-ray imaging device according to the present invention includes the steps of heating and flowing insulating oil (step 10), and discharging the heated insulating oil in the direction of gravity inside the first accommodating container (step) 20), flowing the insulating oil discharged into the first accommodating container into a second accommodating container, and removing air by applying an up pressure to the second accommodating container in which the insulating oil is accommodated (step 30); Flowing the insulating oil in the second accommodating container, accommodating it in the accommodating housing, arranging a casing to be filled with insulating oil inside the accommodating housing, and filling the insulating oil while flowing the accommodating housing in which the casing is disposed (step 40) and applying a negative pressure to the inside of the accommodation housing (step 50).

In the method for manufacturing a portable X-ray imaging device according to the present invention, first, the insulating oil is heated through the heating device member 10 and flows toward the first air removal member 20 while heating. (Step 10)

As described above, by heating the insulating oil through the heating device member 10, air particles present in the insulating oil may be actively flowed and evaporated.

In this state, the heated insulating oil flowing toward the first air removing member 20 is discharged downward from the inside of the first air removing member 20 .

At this time, the insulating oil heated as described above is sprayed through the spray nozzle 22 installed at the upper end of the first receiving container 21 of the first air removing member 20 .

Thus, the insulating oil heated by the heating device member 10 may be sprayed inside the first accommodating container 21 in the form of fine droplets.

Thereby, the air (bubbles) present in the insulating oil is evaporated and scattered.

And, the insulating oil in a heated state injected into the first accommodating container 21 flows along the surface of the insulating oil flow member 24 .

Thus, along the surface of the insulating oil flow member 24 configured to increase the surface area as much as possible, while the sprayed insulating oil in the heated state flows, the insulating oil in the form of droplets is also configured to spread over a wide area as much as possible.

And, it is configured to apply vibration while the insulating oil flows along the insulating oil flow member 24 through the vibration generating member 27 .

Accordingly, air (bubbles) existing in the heated and sprayed insulating oil can flow out very smoothly into the inner space of the first air removing member 20 .

In this state, through the negative pressure applying unit 28 installed in the first air removing member 20, it is configured to apply a negative pressure to the inside of the first accommodating container 21 to suck the leaked air.

In addition, in the process in which the injected insulating oil flows through the surface of the insulating fluid member 24 by heating the insulating fluid member 24 through the heating unit 26 and vibrating it through the vibration generating member 27, air It may be configured to be heated and evaporated in a vibrating state.

In addition, lattice-shaped recesses 244 may be formed on the surface of the insulating fluid member 24 to further increase the surface area of the insulating fluid member 24 to more actively evaporate air present in the insulating oil. have.

Thus, by increasing the path through which the injected insulating oil flows along the surface of the insulating fluid flow member 24, it may be configured to further enhance the evaporative scattering effect of air present in the insulating oil.

The insulating oil from which air particles are removed through the first air removing member 20 flows through the valve 29 and flows to the second air removing member 30 .

The insulating oil flowing to the second air removing member 30 is cooled in the second accommodating container 31 .

At this time, by applying a negative pressure through the negative pressure applying unit 32 installed in the second air removing member 30 , the negative pressure applying unit applies the air that is scattered while the insulating oil is falling into the second air removing member 30 . (32) is configured to suction through and remove.

Alternatively, an adsorption member 36 for adsorbing the insulating oil may be disposed inside the second air removal member 30 so that the insulating oil flows downward through the adsorption member 36 .

At this time, air may be sucked through the negative pressure applying unit 32 while applying vibration to the adsorption member 36 .

Thus, by vibration applied while the insulating oil flows through the adsorption member 36 , the air remaining in the insulating oil is dispersed into the second accommodating container 31 and sucked.

In addition, by installing a heating means 34 for heating the insulating oil under the adsorption member 36 to heat the insulating oil flowing through the adsorption member 36, the evaporation and scattering effect of air can be further enhanced.

Thereafter, the insulating oil in a state in which air bubbles are removed by the second air removing member 30 flows through the valve 39 and flows into the receiving housing 52 of the insulating oil injection member 50 .

In addition, an X-ray imaging device in which various circuit elements 62 , a boosting transformer 66 , and an X-ray tube 68 are disposed inside the casing 63 is disposed in the accommodation housing 52 .

In this state, a negative pressure is applied through the negative pressure applying unit 56 while reciprocating the housing 52 of the insulating oil injection member 50 about the shaft 54 .

At this time, it is configured to check whether an appropriate negative pressure is applied through the pressure sensor unit 57 installed in the accommodation housing 52 .

As described above, by flowing the receiving housing 52 in a reciprocating motion method, the insulating oil is filled into the casing 63 .

By applying a negative pressure while flowing the casing 61 as described above, the insulating oil can flow smoothly to the corners inside the casing 61 .

And, by sucking and removing air from the inner space of the casing 61 generated due to the filling of the insulating oil in this process through the negative pressure applying unit 56, the insulating oil flows smoothly into the corners inside the casing 61 Therefore, it is possible to increase the filling speed of the insulating oil.

As mentioned above, the terms used in the embodiments of the present invention have the same meanings as commonly understood by those of ordinary skill in the art to which the present invention pertains.

Although the present invention has been described with reference to the limited embodiments and drawings, the embodiments are not intended to limit the technical spirit of the present invention, but rather to explain, the technical spirit of the present invention is not limited thereto, and the present invention pertains to By those of ordinary skill in the art, various modifications and variations will be possible within the technical spirit of the present invention and the equivalent scope of the claims to be followed.

Accordingly, the protection scope of the present invention should be interpreted by the claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

And, as long as it is within the scope of the object of the present invention, all the components may be configured by selectively combining one or more.

The terms "included" or "consisting of" above mean that the corresponding component may be included, and should be construed as being able to additionally include other components.

10: heating device member
20: first air removal member
30: second air removal member
50: insulating oil injection member

Claims (16)

heating and flowing the insulating oil;
discharging the heated insulating oil in the direction of gravity from the inside of the first container to flow while applying vibration;
flowing the insulating oil flowing in the first accommodating container into the second accommodating container;
removing air by applying an up pressure to the second accommodating container in which the insulating oil is accommodated;
flowing the insulating oil in the second accommodating container and accommodating it in the accommodating housing, and disposing a casing to be filled with the insulating oil in the accommodating housing;
filling the insulating oil while flowing the accommodation housing in which the casing is disposed;
Including the step of applying a negative pressure to the inside of the housing housing,
A nozzle for injection is installed at the upper end inside the first container, and the heated insulating oil is discharged through the nozzle for injection,
A method of manufacturing a portable X-ray imaging device, characterized in that an insulating fluid member is installed inside the first accommodating container. The method of claim 1,
The insulating fluid member is made of a stainless steel material, and a plurality of openings are formed therein. 3. The method of claim 2,
A method of manufacturing a portable X-ray imaging device, characterized in that lattice-shaped recesses are formed on the surface of the insulating fluid member. 3. The method of claim 2,
The method of manufacturing a portable X-ray imaging device, characterized in that the insulating fluid member is configured to be heated while vibrating. The method of claim 1,
A method of manufacturing a portable X-ray imaging device, characterized in that it is configured to remove the air inside the insulating oil sprayed by applying an up pressure to the first accommodation container. The method of claim 1,
A method of manufacturing a portable X-ray imaging device, characterized in that a heating means for heating the insulating oil accommodated in the second accommodating container is installed. The method of claim 1,
A method of manufacturing a portable X-ray imaging device, characterized in that an adsorption member for adsorbing the contained insulating oil is disposed inside the second container. 8. The method of claim 7,
A method of manufacturing a portable X-ray imaging device, characterized in that a vibration generating member for applying vibration to the adsorption member is disposed inside the second accommodating container. a heating device member for heating and flowing the insulating oil;
a first air removing member for removing air in the insulating oil discharged while discharging the heated insulating oil in a gravity direction;
a second air removing member for removing air bubbles by applying an up pressure while accommodating the insulating oil;
and an insulating oil injection member for accommodating the insulating oil and the insulating oil filling target casing therein and injecting the insulating oil into the casing,
A negative pressure applying part is installed on the housing housing of the insulating oil injection member, and the housing housing is configured to reciprocate about an axis,
A nozzle for injection is installed at the upper end of the first air removal member, and the heated insulating oil is sprayed and discharged through the nozzle for injection,
An insulating oil flow member for flowing the insulating oil sprayed along the surface is installed inside the first air removal member,
The insulating fluid member is formed of a stainless steel material, and a plurality of openings are formed therein;
The insulating fluid member is a portable X-ray imaging device manufacturing apparatus, characterized in that configured to vibrate while being heated. 10. The method of claim 9,
A portable X-ray imaging device manufacturing apparatus, characterized in that the lattice-shaped recesses are formed on the surface of the insulating fluid member. 10. The method of claim 9,
A portable X-ray imaging device manufacturing apparatus, characterized in that it is configured to remove the air inside the insulating oil sprayed by applying a pressure to the first air removing member. 10. The method of claim 9,
A portable X-ray imaging device manufacturing apparatus, characterized in that the second air removal member is provided with a heating means for heating the contained insulating oil. 10. The method of claim 9,
An apparatus for manufacturing a portable X-ray imaging device, characterized in that an adsorption member for adsorbing the received insulating oil is disposed inside the second air removing member. 14. The method of claim 13,
A portable X-ray imaging device manufacturing apparatus, characterized in that a vibration generating member for applying vibration to the suction member is disposed inside the second air removing member. delete delete

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