JP2011108415A - X-ray tube device and manufacturing method of x-ray tube device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an X-ray tube device and a manufacturing method of the X-ray tube device with increase of weight and size restrained and of high reliability over a long period of time. <P>SOLUTION: The X-ray tube device 10 is provided with an X-ray tube 30, a housing 20, cooling liquid 7, high-voltage insulation member 40, high-voltage supply terminal 44, and electric insulation member 60. The high-voltage insulation member 40 includes a heat-transfer face 43 and an end face 41, constituting a part of a vacuum envelope 31 and equipped with an anode target 35a. The electric insulation member 60 includes a flat end face 61 having an area larger than that of the end face 41, the other end face 62 adhered to the end face 41, and a through-hole 63. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an X-ray tube apparatus and a method for manufacturing the X-ray tube apparatus.

  X-ray tube apparatuses are used in many applications such as medical diagnostic equipment. The X-ray tube device operates by being supplied with a high voltage from a high voltage generator via a high voltage cable. A high voltage connector is provided at the tip of the high voltage cable. The high voltage connector is detachably attached to a high voltage insulating member which is a connection portion on the X-ray tube side. A high voltage is supplied to the cathode or anode target of the X-ray tube via the high voltage connector.

  As a high voltage connector, there is known a high voltage connector that is attached to a high voltage insulating member of an X-ray tube by applying pressure (see, for example, Patent Documents 1 to 3). By applying pressure, the air layer between the electrically insulating rubber portion of the high-voltage connector and the high-voltage insulating member of the X-ray tube is removed, and the surfaces of each other are firmly adhered to each other. As a result, it is possible to cut off the discharge along the adhesion interface. The merit of using such a high voltage connector is that the X-ray tube device is more compact than when insulating oil is used for high voltage insulation.

  In the X-ray tube device described above, the crimping surface between the electrically insulating rubber portion of the high voltage connector and the high voltage insulating member on the X-ray tube side is a tapered surface. By making the crimping surface a tapered surface that is long in the tube axis direction, high voltage insulation can be maintained even when the outer diameter of the high voltage insulating member on the X-ray tube side is small.

Japanese Patent Laid-Open No. 2002-216682 US Pat. No. 6,556,654 JP 2009-117083 A

  The X-ray tube apparatus disclosed in Patent Document 1 and Patent Document 2 described above has the following problems. That is, the crimping surface between the high voltage connector electrically insulating rubber portion and the high voltage insulating member on the X-ray tube side becomes longer in the tube axis direction, which is an obstacle to the compact design of the X-ray tube device.

  Patent Document 3 discloses an example in which the pressure-bonding surface between the electrically insulating rubber portion of the high-voltage connector and the high-voltage insulating member on the X-ray tube side is a flat surface. As a result, it is possible to realize a high-voltage connector connection portion that is short in the tube axis direction.

  In this case, in order to ensure a sufficient insulation distance, it is necessary to increase the dimension in the radial direction as much as it is compact in the tube axis direction. However, when the size of the rotary anode type X-ray tube is small, the diameter of the vacuum envelope at the location facing the stator coil is small, so the outer diameter of the high voltage insulating member to which the anode target is attached is also small. In this case, it is difficult to secure a sufficient insulation distance even if the high voltage insulating member is used as a connection portion with the high voltage connector.

  If the diameter of the vacuum envelope at a location facing the stator coil is simply increased, the outer diameter of the stator coil is increased or the weight of the X-ray tube component is increased as compared with the conventional case. As a result, it becomes difficult to design the X-ray tube apparatus to be lightweight and compact.

  The present invention has been made in view of the above points, and an object of the present invention is to provide an X-ray tube apparatus and a method for manufacturing the X-ray tube apparatus that can suppress an increase in weight and an increase in size and are highly reliable over a long period of time. is there.

In order to solve the above problems, an X-ray tube apparatus according to an aspect of the present invention provides:
An X-ray tube comprising: a vacuum envelope; an anode target provided in the vacuum envelope; and a cathode provided in the vacuum envelope and emitting electrons that irradiate the anode target.
A housing having an opening and containing the X-ray tube;
A coolant filled between the X-ray tube and the housing;
A heat transfer surface that directly or indirectly contacts the coolant and transfers heat to the coolant, and an adhesive surface that faces the opening of the housing, and constitutes a part of the vacuum envelope; A high voltage insulating member to which the anode target or cathode is attached, and
A high voltage supply terminal provided on the high voltage insulating member and exposed to the outside of the housing;
A flat end surface exposed to the outside of the housing and having an area larger than the bonding surface; the other end surface bonded to the bonding surface of the high voltage insulating member; and the high voltage supply terminal to the outside of the housing. And an electrically insulating member including a through hole that opens to the end surface and the other end surface so as to maintain exposure.

Moreover, the manufacturing method of the X-ray tube apparatus which concerns on the other aspect of this invention is the following.
A vacuum envelope, an anode target provided in the vacuum envelope, a cathode provided in the vacuum envelope and emitting electrons to be irradiated to the anode target, a heat transfer surface and an adhesive surface An X-ray comprising a high-voltage insulating member that constitutes a part of the vacuum envelope and to which the anode target or the cathode is attached in a vacuum, and a high-voltage supply terminal provided on the high-voltage insulating member Prepare a tube,
Preparing an electrically insulating member including a flat end surface having an area larger than the adhesive surface, the other end surface, and a through hole opening in the end surface and the other end surface;
Applying an adhesive to at least one of the adhesive surface and the other end surface;
The other end surface is brought into contact with the adhesive surface through the adhesive,
After the contact, press the electrical insulating member, adhere the electrical insulating member to the high voltage insulating member,
Prepare a housing with an opening,
The X-ray tube provided with the electrically insulating member is accommodated in the housing, the adhesive surface is opposed to the opening, the end surface and the high voltage supply terminal are exposed to the outside of the housing, and the through hole Maintains exposure of the high voltage supply terminal to the outside of the housing;
A coolant is filled between the X-ray tube and the housing.

Moreover, the manufacturing method of the X-ray tube apparatus which concerns on the other aspect of this invention is the following.
A vacuum envelope, an anode target provided in the vacuum envelope, a cathode provided in the vacuum envelope and emitting electrons to be irradiated to the anode target, a heat transfer surface and an adhesive surface An X-ray comprising a high-voltage insulating member that constitutes a part of the vacuum envelope and to which the anode target or the cathode is attached in a vacuum, and a high-voltage supply terminal provided on the high-voltage insulating member Prepare a tube,
The adhesive surface of the high voltage insulating member is carried into the mold material tank, and the high voltage supply terminal is inserted into a through hole or a recess formed in the mold material tank.
Injecting mold material into the mold material tank,
The injected mold material is cured, a flat end surface having an area larger than the bonding surface, the other end surface directly bonded to the bonding surface, and the high voltage supply terminal are surrounded and opened to the end surface and the other end surface. And forming an electrically insulating member including a through hole,
Prepare a housing with an opening,
The X-ray tube provided with the electrically insulating member is accommodated in the housing, the adhesive surface is opposed to the opening, the end surface and the high voltage supply terminal are exposed to the outside of the housing, and the electrical insulation is performed. The through hole of the conductive member maintains the exposure of the high voltage supply terminal to the outside of the housing;
A coolant is filled between the X-ray tube and the housing.

  According to the present invention, an increase in weight and an increase in size can be suppressed, and a highly reliable X-ray tube apparatus and a method for manufacturing the X-ray tube apparatus can be provided over a long period of time.

1 is an exploded longitudinal sectional view showing an X-ray tube apparatus according to a first embodiment of the present invention. It is a front view which shows the junction part shown in FIG. It is a top view which shows the junction part shown in FIG. It is a figure which shows the state which manufactures the X-ray tube apparatus which concerns on the said 1st Embodiment. It is a longitudinal cross-sectional view which decomposes | disassembles and shows the modification of the X-ray tube apparatus which concerns on the said 1st Embodiment. It is sectional drawing which shows a part of X-ray tube apparatus shown in FIG. It is a front view which shows the modification of the junction part of the X-ray tube apparatus which concerns on the said 1st Embodiment. It is a top view which shows the modification of the junction part of the X-ray tube apparatus which concerns on the said 1st Embodiment. It is a longitudinal cross-sectional view which decomposes | disassembles and shows the X-ray tube apparatus which concerns on the 2nd Embodiment of this invention. It is a longitudinal cross-sectional view which decomposes | disassembles and shows the X-ray tube apparatus which concerns on the 3rd Embodiment of this invention. It is a longitudinal cross-sectional view which decomposes | disassembles and shows the X-ray tube apparatus which concerns on the 4th Embodiment of this invention. It is a longitudinal cross-sectional view which decomposes | disassembles and shows the X-ray tube apparatus which concerns on the 5th Embodiment of this invention. It is a figure which shows the state which manufactures the X-ray tube apparatus which concerns on the said 5th Embodiment. It is a longitudinal cross-sectional view which decomposes | disassembles and shows the X-ray tube apparatus which concerns on the 6th Embodiment of this invention. It is a figure which shows the state which manufactures the X-ray tube apparatus which concerns on the said 6th Embodiment. It is a longitudinal cross-sectional view which decomposes | disassembles and shows the other modification of the X-ray tube apparatus which concerns on the said 1st Embodiment.

Hereinafter, an X-ray tube apparatus and a method of manufacturing the X-ray tube apparatus according to the first embodiment of the present invention will be described in detail with reference to the drawings. First, the configuration of the X-ray tube apparatus will be described.
As shown in FIG. 1, the X-ray tube apparatus 10 includes a housing 20, an X-ray tube 30 accommodated in the housing 20, and a coolant 7 filled in the housing 20.

  The housing 20 has a housing body 20a and an annular portion 20b. The housing body 20a is integrally formed with a cylindrical portion 20c and an annular portion 20d provided at one end of the cylindrical portion 20c. A radiation window 24 for radiating X-rays to the outside is formed in a part of the cylindrical portion 20c. The annular portion 20b is attached to the other end of the cylindrical portion 20c (housing main body 20a). Here, the annular portion 20b is detachably screwed (not shown) to the cylindrical portion 20c.

  The housing 20 is provided with a rubber bellows 21 to adjust the pressure of the coolant 7. A coolant circulation pump 22 and a heat exchanger 23 are provided outside the housing 20. The coolant circulation pump 22 is connected to the housing 20. The coolant circulation pump 22 creates a flow of the coolant 7 in the housing 20. The heat exchanger 23 is connected between the housing 20 and the coolant circulation pump 22. The heat exchanger 23 releases the heat of the coolant 7 to the outside.

  The X-ray tube 30 includes a vacuum envelope 31. The vacuum envelope 31 includes a vacuum container 32 formed of a metal such as copper, stainless steel, and aluminum, a high voltage insulating member 40, and a high voltage insulating member 50. The anode target 35 a and the cathode 36 are accommodated in the vacuum envelope 31. The inside of the vacuum envelope 31 is in a vacuum state. The radiation window 33 is airtightly provided in the vacuum container 32. Here, the radiation window 33 is made of beryllium.

The high voltage insulating member 40 forms a part of the vacuum envelope 31. An anode target 35 a is indirectly attached to the high voltage insulating member 40. The high voltage insulating member 40 includes a heat transfer surface 43 that directly or indirectly contacts the coolant 7 and transfers heat to the coolant 7, and an end surface 41 that faces the opening of the housing 20 (annular portion 20 d). . Specifically, the high-voltage insulating member 40 includes a cylindrical portion 46 having a heat transfer surface 43 and an annular bottom portion 47 that closes one end side of the cylindrical portion 46 and has the heat transfer surface 43 and the end surface 41. It is integrally formed.
In this embodiment, the heat transfer surface 43 is in direct contact with the coolant 7. The end surface 41 is a flat surface. The end surface 41 functions as an adhesive surface.

  A high voltage supply terminal 44 is provided on the bottom 47. The high voltage supply terminal 44 is provided in the opening of the bottom 47. The high voltage supply terminal 44 supplies a high voltage to the anode 35. The high voltage supply terminal 44 is exposed outside the housing 20. The high voltage supply terminal 44 is a metal terminal and is brazed to the annular bottom 47.

  The anode 35 has an anode target 35a. The anode target 35a has a target layer 35t. The target layer 35t emits X-rays when irradiated with electrons.

  The X-ray tube apparatus 10 includes a stator coil 910, a rotor 920, a bearing 930, a fixed body 1, a rotating body 2, and a support body 35b. The fixed body 1 is formed in a columnar shape. The rotating body 2 is formed in a cylindrical shape and is provided coaxially with the fixed body 1. A rotor 920 is attached to the outer surface of the rotating body 2. Stator coil 910 is attached to housing 20 and faces rotor 920. The bearing 930 is provided in a gap between the fixed body 1 and the rotating body 2.

  The support 35 b is located inside the vacuum envelope 31. The support 35b has a tapered hole, and the tapered portion of the fixed body 1 is fitted into the tapered hole. The support 35b indirectly supports the anode target 35a. An annular slit groove is formed in the support 35b.

  The support 35b is located at a distance from the bottom 47. The support body 35 b includes a joint portion 35 c joined to the inner surface of the cylindrical portion 46. The joint 35c is brazed to the support 35b. The support 35b including the joint portion 35c is formed of metal.

  As shown in FIGS. 1, 2, and 3, the joint portion 35 c exhibits flexibility. For this reason, the joint part 35c is elastically deformed at a high temperature to relieve at least a part of the thermal stress. In this embodiment, the joint portion 35 c has an uneven surface 35 d that faces the inner surface of the cylindrical portion 46. The convex portions 35e are arranged next to each other around the joint portion 35c. The convex portion 35e of the joint portion 35c is joined to the inner surface of the cylindrical portion 46. In addition, the support body 35b should just be joined to the inner surface of the high voltage insulation member 40 through the flexible component which elastically deforms at high temperature and relieves at least a part of thermal stress.

  As shown in FIG. 1, the metallized layer 11 is formed on the inner surface of the high voltage insulating member 40. The metallized layer 11 is connected to the high voltage supply terminal 44 and the junction 35c. Therefore, a high voltage is supplied to the anode target 35 a through the high voltage supply terminal 44, the metallized layer 11, the support 35 b, the fixed body 1, the bearing 930, and the rotating body 2.

  By making the shape of the metallized layer 11 connecting the high voltage supply terminal 44 and the joint part 35 c into a narrow band shape, unnecessary heat conduction from the anode 35 through the metallized layer 11 can be suppressed.

  The electrically insulating member 60 is formed in a disk shape having an outer diameter larger than that of the bottom portion 47. The electrically insulating member 60 includes an end surface 61, the other end surface 62, and a through hole 63. The end surface 61 is exposed to the outside of the housing 20 and has a larger area than the end surface (adhesion surface) 41. The end surface 61 is a flat surface. The other end surface 62 has a larger area than the end surface (adhesion surface) 41. The through hole 63 opens in the end surface 61 and the other end surface 62. The through hole 63 maintains the exposure of the high voltage supply terminal 44 to the outside of the housing 20. The other end surface 62 is bonded (permanently bonded) to the end surface (bonded surface) 41 via the adhesive 14.

The electrically insulating member 60 is made of a ceramic material or a glass material. Examples of the ceramic material include aluminum oxide, zirconia (zirconium oxide), silicon nitride, and aluminum nitride. Examples of the glass material include quartz glass, sapphire, non-alkali glass, and the like.
The adhesive 14 can use a material mainly composed of an epoxy resin or a silicone resin.

  The support member 25 is formed in an annular shape. The electrically insulating member 60 is attached to the support member 25. The support member 25 faces the annular portion 20d. The annular portion 20 d has an annular groove formed on the side facing the support member 25. A gap between the support member 25 and the annular portion 20d is sealed by an annular O-ring provided in the groove portion. The O-ring has a function of preventing leakage of the coolant 7 from the gap between the support member 25 and the annular portion 20d to the outside.

The high voltage insulating member 50 forms a part of the vacuum envelope 31. The cathode 36 is indirectly attached to the high voltage insulating member 50. The high voltage insulating member 50 includes a heat transfer surface 53 that directly or indirectly contacts the coolant 7 and transfers heat to the coolant 7, and an end surface 51 that faces the opening of the housing 20 (annular portion 20 b). . Specifically, the high-voltage insulating member 50 is formed integrally with a cylindrical portion 56 having a heat transfer surface 53 and an annular bottom portion 57 having an end surface 51 that closes one end side of the cylindrical portion 56. Has been.
In this embodiment, the heat transfer surface 53 is in direct contact with the coolant 7. The end surface 51 is a flat surface.

  Inside the high voltage insulating member 50, a high voltage supply terminal 54 connected to the cathode 36 and led out to the end face 51 side is provided. The high voltage supply terminal 54 is supported by a KOV member 55 that is a low expansion alloy with respect to the high voltage insulating member 50. The high voltage supply terminal 54 and the high voltage insulating member 50 and the KOV member 55 and the high voltage insulating member 50 are brazed. The high voltage supply terminal 54 supplies a high voltage to the cathode 36. The high voltage supply terminal 54 is exposed outside the housing 20. The high voltage supply terminal 54 is a metal terminal.

  Although not shown, the cathode 36 has an electron emission source that emits electrons. For this reason, the cathode 36 can emit the electrons irradiated to the anode target 35a (target layer 35t).

  The high voltage insulating members 40 and 50 can be formed of the same material as the electrically insulating member 60. The high voltage insulating members 40 and 50 are preferably formed using ceramics such as aluminum nitride or beryllia having a high thermal conductivity.

  The support member 26 is formed in an annular shape. The high voltage insulating member 50 is attached to the support member 26. The support member 26 faces the annular portion 20b. The annular portion 20 b has an annular groove formed on the side facing the support member 26. A gap between the support member 26 and the annular portion 20b is sealed by an annular O-ring provided in the groove portion. The O-ring has a function of preventing leakage of the coolant 7 from the gap between the support member 26 and the annular portion 20b to the outside.

  The high-voltage connector 100 includes a bottomed cylindrical housing 101, a high-voltage cable 102 having a tip inserted into the housing 101, and the housing 101 filled with the terminal 102a of the high-voltage cable 102. An electrical insulating material 103 that is fixed toward the part side, and a silicone plate 104 made of a silicone resin material that is inserted between the electrical insulating material 103 and an end surface 61 of the electrical insulating member 60 are provided.

  In this embodiment, the electrical insulating material 103 of the high voltage connector 100 is in intimate contact with the end face 61 of the electrical insulating member 60. The electrical insulating material 103 may be in direct contact with the end surface 61. For example, an electrically insulating rubber or an epoxy resin can be used as the electrically insulating material 103. The high voltage connector 100 provides a high voltage to the high voltage supply terminal 44.

  When the high voltage connector 100 configured in this way is attached to the housing 20, the silicone plate 104 is pressed so as to be in close contact with the electrical insulating material 103 and the end surface 61 of the electrical insulating member 60.

  The high-voltage connector 200 includes a bottomed cylindrical housing 201, a high-voltage cable 202 having a tip inserted into the housing 201, and the housing 201 filled with a terminal 202a of the high-voltage cable 202. An electrical insulating material 203 that is fixed toward the part side, and a silicone plate 204 made of a silicone resin material inserted between the electrical insulating material 203 and the end face 51 of the high-voltage insulating member 50 are provided.

  In this embodiment, the electrical insulating material 203 of the high voltage connector 200 is in intimate contact with the end face 51 of the high voltage insulating member 50. The electrical insulating material 203 may be in direct contact with the end face 51. As the electrical insulating material 203, for example, an electrical insulating rubber or an epoxy resin can be used. The high voltage connector 200 applies a high voltage to the high voltage supply terminal 54.

  When the high voltage connector 200 configured in this manner is attached to the housing 20, the silicone plate 204 is pressed so as to be in close contact with the electrical insulating material 203 and the end face 51 of the high voltage insulating member 50.

  The coolant 7 is filled in the housing 20 and fills the space between the X-ray tube 30 and the housing 20. As the coolant 7, insulating oil or an aqueous coolant can be used. In this embodiment, an aqueous coolant is used as the coolant 7.

In the X-ray tube apparatus 10 configured as described above, when a predetermined current is applied to the stator coil 910, the rotor 920 rotates and the anode target 35a (anode 35) rotates. Next, when a predetermined high voltage is applied to the high voltage connectors 100 and 200, electrons are irradiated from the cathode 36 to the target layer 35t of the anode target 35a, and X-rays are emitted from the target layers 35t to the outside through the radiation windows 24 and 33. Is done.
As described above, the X-ray tube device 10 is formed.

Next, a method for manufacturing the X-ray tube apparatus 10 will be described.
As shown in FIG. 4, first, an X having a vacuum envelope 31, an anode 35, a cathode 36, high voltage insulating members 40 and 50, high voltage supply terminals 44 and 54, and a KOV member 55. A wire tube 30 is prepared.

  Next, the X-ray tube 30 is carried into the vacuum chamber 90 containing the jig 91. The jig 91 has a housing 92 and a support member 93. After carrying in the X-ray tube 30, the X-ray tube 30 is placed on the housing 92. The housing 92 is formed with one end closed. Here, the housing 92 supports the vacuum vessel 32. Subsequently, a support member 93 is provided at the other end of the housing 92. Thereafter, the stator coil 910 is fitted into the high voltage insulating member 40, and the stator coil 910 is mounted on the support member 93.

  On the other hand, an electrically insulating member 60 is prepared. Here, the support member 25 is attached to the prepared electrical insulating member 60. Next, the support member 25 is placed on the elevating mechanism 94 in the vacuum chamber 90 so that the other end surface 62 faces the end surface (adhesion surface) 41. Subsequently, a weight 95 is placed on the support member 25.

  Subsequently, the adhesive 14 is applied to at least one of the end surface (adhesion surface) 41 and the other end surface 62. Here, the adhesive 14 was applied to both the end surface (adhesion surface) 41 and the other end surface 62. After applying the adhesive 14, the inside of the vacuum chamber 90 is evacuated. Thereafter, the electrical insulating member 60 is lowered by the elevating mechanism 94 and the other end surface 62 is brought into contact with the end surface (adhesion surface) 41 with the adhesive 14 interposed therebetween.

  After the contact, the lifting mechanism 94 is separated from the support member 25. Thereby, the weight 95 presses the electrical insulating member 60. Then, when the adhesive 14 is cured, the electrical insulating member 60 is bonded to the high voltage insulating member 40 via the adhesive 14. In addition, by bonding in a vacuum, it is possible to prevent bubbles such as air that may remain at the bonding interface of the adhesive 14 from remaining.

  As shown in FIG. 1, a housing 20 is then prepared. Specifically, a housing body 20a having an opening is prepared. Next, the X-ray tube 30 provided with the stator coil 910, the electrically insulating member 60, and the support member 25 is accommodated in the housing body 20a. At this time, the end surface 41 is opposed to the opening of the housing 20 (annular portion 20 d), and the end surface 61 and the high voltage supply terminal 44 are exposed to the outside of the housing 20. The through hole 63 maintains the exposure of the high voltage supply terminal 44 to the outside of the housing 20.

  Subsequently, after attaching the support member 26 to the high-voltage insulating member 50, the annular portion 20b is screwed to the other end of the housing body 20a. Thereafter, the coolant 7 is filled between the X-ray tube 30 and the housing main body 20a. Thereby, the housing 20 that holds the coolant 7 in a liquid-tight manner is formed. Thereafter, the coolant circulation pump 22, the heat exchanger 23, and the high voltage connectors 100 and 200 are attached to the housing 20, thereby completing the X-ray tube device 10.

  According to the X-ray tube apparatus 10 and the method for manufacturing the X-ray tube apparatus 10 according to the first embodiment configured as described above, the X-ray tube apparatus 10 includes the vacuum envelope 31 and the anode target 35a. An X-ray tube 30 having a cathode 36, a housing 20, a coolant 7, high-voltage insulating members 40 and 50, high-voltage supply terminals 44 and 54, and an electrical insulating member 60. ing.

  The electrically insulating member 60 has a flat end surface 61 having an area larger than the end surface (adhesion surface) 41 and an area larger than the end surface (adhesion surface) 41, and the end surface (adhesion surface) 41 of the high-voltage insulation member 40. And the other end surface 62 bonded to the other end. In this embodiment, the diameter of the electrically insulating member 60 is larger than the diameter of the bottom 47. In the manufacturing process in which the electrically insulating member 60 is bonded, the stator coil 910 may be fitted in the high voltage insulating member 40 in advance.

  Thereby, the insulation of the connection part of the high voltage connector 100 can be ensured over a long period of time without being concerned with the size of the X-ray tube 30. Since it is not necessary to increase the diameters of the high-voltage insulating member 40 and the stator coil 910, an increase in weight and an increase in size of the X-ray tube device 10 (X-ray tube 30) can be suppressed.

  By bonding the high voltage insulating member 40 and the electrical insulating member 60 so that no bubbles remain at the bonding interface, it is possible to obtain the same insulating characteristics as when the high voltage insulating member 40 and the electrical insulating member 60 are integrally formed. it can. That is, the discharge path along the adhesion interface can be cut off, and high electrical insulation characteristics can be obtained.

  The adhesion interface between the high voltage insulating member 40 and the electrical insulating member 60 is superior to the adhesion interface between the high voltage connector 100 and the electrical insulating member 60 in electrical insulation. Here, the term “adhesion” means permanent adhesion, and cannot be separated unless it is destroyed. Adhesion means pressing and leaves when pressure is removed. In the case of close contact, electrical insulation characteristics are greatly affected by subtle changes in pressure.

Further, when the X-ray irradiation continues, the temperature of the anode target 35a and the cathode 36 increases. The heat of the anode target 35a is transmitted to the high voltage insulating member 40 through the rotating body 2, the bearing 930, the fixed body 1 and the support body 35b. The heat of the cathode 36 is transmitted to the high voltage insulating member 50 through the high voltage supply terminal 54. The high voltage insulating members 40 and 50 are cooled because the heat transfer surfaces 43 and 53 are in contact with the coolant 7. That is, since the heat of the anode 35 and the cathode 36 is dissipated into the coolant 7 and the temperature of the high voltage connectors 100 and 200 can be lowered, thermal deformation of the high voltage connectors 100 and 200 is suppressed. As a result, the discharge along the contact interface between the high voltage connectors 100 and 200 and the end face 51 and the end face 61 is suppressed, and insulation can be ensured over a long period.
The joint portion 35c exhibits flexibility. For this reason, stabilization of the favorable connection state of the anode 35 and the high voltage insulating member 40 can be achieved.

The coolant 7 is circulated by the coolant circulation pump 22, and heat is released to the outside by the heat exchanger 23. In addition, since the water-system coolant which has the highest heat transfer rate and has water as a main component can be used as the coolant 7, the high-voltage insulating members 40 and 50 can be efficiently cooled. Since the water-based coolant 7 has a high heat transfer coefficient, the entire coolant 7 has a more uniform temperature. Further, since the water-based coolant 7 has a larger specific heat than the insulating oil (about twice that of the insulating oil), the temperature rise of the coolant due to the heat radiation of the X-ray tube 30 can be kept low.
From the above, an increase in weight and an increase in size can be suppressed, and a highly reliable X-ray tube device 10 and a method for manufacturing the X-ray tube device 10 can be obtained over a long period of time.

  Here, as shown in FIGS. 5 and 6, in the X-ray tube device 10, the high voltage insulating member 40 further includes a heat transfer promoting portion 16 provided on the heat transfer surface 43 and in contact with the coolant 7. You can leave. The heat transfer promotion part 16 is a bowl-shaped enclosure joined to the heat transfer surface 43 by, for example, brazing.

  Each of the heat transfer promotion portions 16 has a V-shaped cross section, extends along the extending direction of the tube portion 46, protrudes outward from the heat transfer surface 43, and heat transfer surface 43 around the tube portion 46. Are formed by a plurality of convex portions 16a arranged adjacent to each other. The heat transfer promoting part 16 is formed of a material having high thermal conductivity such as metal. In addition, the cylinder part 46 is in contact with the coolant 7 indirectly through the heat transfer promotion part 16.

  In this case, since the heat transfer promotion part 16 is provided on the heat transfer surface 43, the surface area in contact with the coolant 7 is increased as compared with the case where the heat transfer promotion part 16 is not provided. That is, the high voltage insulating member 40 can be further cooled, thermal deformation of the high voltage connector 100 can be further suppressed, and discharge along the adhesion interface between the high voltage connector 100 and the end surface 61 can be further suppressed. it can.

  The shape of the heat transfer accelerating portion 16 is not limited to the above-described example, and can be variously modified as long as the total surface area in contact with the coolant 7 can be increased even if the shape is changed. Moreover, the heat transfer promotion part 16 may be an uneven pattern formed on the surface of the high voltage insulating member 40 itself. Thereby, the thermal deformation of the high voltage connector 100 can be suppressed, and the discharge along the adhesion interface between the high voltage connector 100 and the end surface 61 can be suppressed.

  Moreover, as shown in FIG.7 and FIG.8, the shape of the junction part 35c is not limited to an above-described example, A various deformation | transformation is possible. For example, the convex portions 35e may be arranged adjacent to each other along the extending direction of the joint portion 35c.

  Next, an X-ray tube apparatus 10 and a method for manufacturing the X-ray tube apparatus 10 according to the second embodiment of the present invention will be described. In this embodiment, the same reference numerals are given to the same functional portions as those in the first embodiment, and detailed description thereof will be omitted.

  As shown in FIG. 9, the electrical insulating member 60 includes an end surface 61, the other end surface 62, and a through hole 63. The electrically insulating member 60 is formed in a bottomed cylindrical shape having a larger outer diameter than the bottom portion 47. Specifically, the electrical insulating member 60 includes a cylindrical portion 66 having the other end surface 62, a disk-shaped bottom portion 67 that closes one end side of the cylindrical portion 66, and has the end surface 61, the other end surface 62, and the through hole 63. have.

  The end surface 61 is exposed to the outside of the housing 20 and has a larger area than the end surface (adhesion surface) 41. The end surface 61 is a flat surface. The other end surface 62 is bonded (permanently bonded) to the outer surface of the bottom 47 via the adhesive 14.

  When bonding the electrical insulating member 60, the adhesive 14 is applied to at least one of the outer surface of the bottom 47 and the other end 62, and the other end 62 is brought into contact with the outer surface of the bottom 47 with the adhesive 14 interposed therebetween. The electric insulating member 60 may be pressed and the electric insulating member 60 may be bonded to the high voltage insulating member 40.

  According to the X-ray tube apparatus 10 and the method of manufacturing the X-ray tube apparatus 10 according to the second embodiment configured as described above, the X-ray tube apparatus 10 includes the vacuum envelope 31 and the anode target 35a. An X-ray tube 30 having a cathode 36, a housing 20, a coolant 7, high-voltage insulating members 40 and 50, high-voltage supply terminals 44 and 54, and an electrical insulating member 60. ing.

  The electrically insulating member 60 includes a flat end surface 61 having an area larger than that of the end surface (bonding surface) 41, and the other end surface 62 bonded to the outer surface of the high voltage insulating member 40. In this embodiment, the diameter of the electrically insulating member 60 is larger than the diameter of the bottom 47. In the manufacturing process in which the electrically insulating member 60 is bonded, the stator coil 910 may be fitted in the high voltage insulating member 40 in advance.

  Thereby, the insulation of the connection part of the high voltage connector 100 can be ensured over a long period of time without being concerned with the size of the X-ray tube 30. Since it is not necessary to increase the diameters of the high-voltage insulating member 40 and the stator coil 910, an increase in weight and an increase in size of the X-ray tube device 10 (X-ray tube 30) can be suppressed.

  In this embodiment, since the electrical insulating member 60 is bonded not only to the end face (adhesion surface) 41 but also to the outer surface of the bottom portion 47, the high-voltage insulating member 40 and the electric insulation member 60 are compared to the first embodiment. The electrical insulation characteristics and adhesive strength between the electrical insulation members 60 can be improved.

In addition, the X-ray tube apparatus 10 of this embodiment can obtain the same effects as the X-ray tube apparatus 10 of the first embodiment described above.
From the above, an increase in weight and an increase in size can be suppressed, and a highly reliable X-ray tube device 10 and a method for manufacturing the X-ray tube device 10 can be obtained over a long period of time.

  Next, an X-ray tube apparatus 10 and a method for manufacturing the X-ray tube apparatus 10 according to a third embodiment of the present invention will be described. In this embodiment, the same reference numerals are given to the same functional portions as those in the first embodiment, and detailed description thereof will be omitted.

  As shown in FIG. 10, the electrical insulating member 60 includes an end surface 61, the other end surface 62, and a through hole 63. The electrically insulating member 60 is formed in a disk shape having an outer diameter larger than that of the bottom portion 47.

  The end surface (adhesion surface) 41 is located inside the housing 20. The end surface 61 is exposed to the outside of the housing 20 and has a larger area than the end surface (adhesion surface) 41. The end surface 61 is a flat surface. The other end surface 62 is bonded (permanently bonded) to the outer surface of the bottom 47 via the adhesive 14.

  In this embodiment, the support member 25 covers the side surface of the electrical insulating member 60 and the side surface of the bottom portion 47. The support member 25 has an annular groove formed on the side facing the side surface of the bottom 47. The gap between the side surface of the bottom 47 and the support member 25 is sealed by an annular O-ring provided in the groove. The O-ring has a function of preventing the coolant 7 from entering the bonding interface of the adhesive 14.

  The support member 25 and the O-ring form a seal portion that prevents the coolant 7 from entering the bonding interface of the adhesive 14. Needless to say, the bonding interface of the adhesive 14 does not contact the coolant 7.

  When the electrical insulating member 60 is bonded, the adhesive 14 is applied to at least one of the outer surface of the bottom 47 and the other end surface 62, and the adhesive 14 is interposed with an O-ring provided in the groove of the support member 25. Then, after the other end surface 62 is brought into contact with the outer surface of the bottom portion 47, the electrical insulating member 60 may be pressed to adhere the electrical insulating member 60 to the high voltage insulating member 40.

  According to the X-ray tube apparatus 10 and the method of manufacturing the X-ray tube apparatus 10 according to the third embodiment configured as described above, the X-ray tube apparatus 10 includes the vacuum envelope 31 and the anode target 35a. An X-ray tube 30 having a cathode 36, a housing 20, a coolant 7, high-voltage insulating members 40 and 50, high-voltage supply terminals 44 and 54, and an electrical insulating member 60. ing.

  The electrically insulating member 60 includes a flat end surface 61 having an area larger than that of the end surface (bonding surface) 41, and the other end surface 62 bonded to the outer surface of the high voltage insulating member 40. In this embodiment, the diameter of the electrically insulating member 60 is larger than the diameter of the bottom 47. In the manufacturing process in which the electrically insulating member 60 is bonded, the stator coil 910 may be fitted in the high voltage insulating member 40 in advance.

  Thereby, the insulation of the connection part of the high voltage connector 100 can be ensured over a long period of time without being concerned with the size of the X-ray tube 30. Since it is not necessary to increase the diameters of the high-voltage insulating member 40 and the stator coil 910, an increase in weight and an increase in size of the X-ray tube device 10 (X-ray tube 30) can be suppressed.

  In this embodiment, since the X-ray tube device 10 is formed so as to prevent the coolant 7 from entering the bonding interface of the adhesive 14, the electric insulating member 60 is peeled off from the high voltage insulating member 40. In addition, it is possible to more reliably prevent the electrical insulation characteristics from being deteriorated. That is, in the X-ray tube apparatus 10, the electrical insulating member 60 is less likely to be peeled off and the electrical insulation characteristics are less likely to be deteriorated as compared to the X-ray tube apparatus 10 of the first embodiment.

In addition, the X-ray tube apparatus 10 of this embodiment can obtain the same effects as the X-ray tube apparatus 10 of the first embodiment described above.
From the above, an increase in weight and an increase in size can be suppressed, and a highly reliable X-ray tube device 10 and a method for manufacturing the X-ray tube device 10 can be obtained over a long period of time.

  Next, an X-ray tube apparatus 10 and a method for manufacturing the X-ray tube apparatus 10 according to a fourth embodiment of the present invention will be described. In this embodiment, the same reference numerals are given to the same functional portions as those in the first embodiment, and detailed description thereof will be omitted.

  As shown in FIG. 11, the electrical insulating member 60 includes an end surface 61, the other end surface 62, and a through hole 63. The electrically insulating member 60 is formed in a disk shape having an outer diameter larger than that of the bottom portion 47.

  The end surface (adhesion surface) 41 is located outside the housing 20. The end surface 61 is exposed to the outside of the housing 20 and has a larger area than the end surface (adhesion surface) 41. The end surface 61 is a flat surface. The other end surface 62 is bonded (permanently bonded) to the outer surface of the bottom 47 via the adhesive 14.

  In this embodiment, the annular portion 20 d has an annular groove formed on the side facing the high voltage insulating member 40. A gap between the annular portion 20d and the high voltage insulating member 40 is sealed by an annular O-ring provided in the groove portion. The O-ring has a function of preventing leakage of the coolant 7 from the gap between the annular portion 20d and the high voltage insulating member 40 to the outside. That is, the annular portion 20 d and the O-ring form a seal portion that prevents the coolant 7 from entering the adhesive interface of the adhesive 14. Needless to say, the bonding interface of the adhesive 14 does not contact the coolant 7.

  When the electrical insulating member 60 is bonded, the adhesive 14 is applied to at least one of the end surface (adhesion surface) 41 and the other end surface 62, and the other end surface 62 is attached to the end surface (adhesion surface) 41 with the adhesive 14 interposed therebetween. After the contact, the electrical insulating member 60 may be pressed to adhere the electrical insulating member 60 to the high voltage insulating member 40.

  According to the X-ray tube apparatus 10 and the method for manufacturing the X-ray tube apparatus 10 according to the fourth embodiment configured as described above, the X-ray tube apparatus 10 includes the vacuum envelope 31 and the anode target 35a. An X-ray tube 30 having a cathode 36, a housing 20, a coolant 7, high-voltage insulating members 40 and 50, high-voltage supply terminals 44 and 54, and an electrical insulating member 60. ing.

  The electrically insulating member 60 includes a flat end surface 61 having an area larger than that of the end surface (bonding surface) 41, and the other end surface 62 bonded to the outer surface of the high voltage insulating member 40. In this embodiment, the diameter of the electrically insulating member 60 is larger than the diameter of the bottom 47. In the manufacturing process in which the electrically insulating member 60 is bonded, the stator coil 910 may be fitted in the high voltage insulating member 40 in advance.

  Thereby, the insulation of the connection part of the high voltage connector 100 can be ensured over a long period of time without being concerned with the size of the X-ray tube 30. Since it is not necessary to increase the diameters of the high-voltage insulating member 40 and the stator coil 910, an increase in weight and an increase in size of the X-ray tube device 10 (X-ray tube 30) can be suppressed.

  In this embodiment, since the X-ray tube device 10 is formed so as to prevent the coolant 7 from entering the bonding interface of the adhesive 14, the electric insulating member 60 is peeled off from the high voltage insulating member 40. In addition, it is possible to more reliably prevent a decrease in electrical insulation characteristics. That is, in the X-ray tube apparatus 10, the electrical insulating member 60 is less likely to be peeled off and the electrical insulation characteristics are less likely to be deteriorated as compared to the X-ray tube apparatus 10 of the first embodiment.

In addition, the X-ray tube apparatus 10 of this embodiment can obtain the same effects as the X-ray tube apparatus 10 of the first embodiment described above.
From the above, an increase in weight and an increase in size can be suppressed, and a highly reliable X-ray tube device 10 and a method for manufacturing the X-ray tube device 10 can be obtained over a long period of time.

  Next, an X-ray tube apparatus 10 and a method for manufacturing the X-ray tube apparatus 10 according to the fifth embodiment of the present invention will be described. In this embodiment, the same reference numerals are given to the same functional portions as those in the first embodiment, and detailed description thereof will be omitted.

  As shown in FIG. 12, the electrical insulating member 60 includes an end surface 61, the other end surface 62, and a through hole 63. The electrically insulating member 60 is formed in a bottomed cylindrical shape having a larger outer diameter than the bottom portion 47. Specifically, the electrical insulating member 60 includes a cylindrical portion 66 having the other end surface 62, a disk-shaped bottom portion 67 that closes one end side of the cylindrical portion 66, and has the end surface 61, the other end surface 62, and the through hole 63. have.

The end surface 61 is exposed to the outside of the housing 20 and has a larger area than the end surface (adhesion surface) 41. The end surface 61 is a flat surface. The electrically insulating member 60 is formed of a molding material, and is directly bonded (permanently bonded) to the outer surface of the bottom 47 and the support member 25. That is, the electrical insulating member 60 itself is formed of a material having adhesiveness. The support member 25 is formed longer than the electrically insulating member 60.
Examples of the molding material include a material mainly composed of an epoxy resin or a silicone resin.

Next, a method for manufacturing the X-ray tube apparatus 10 will be described.
As shown in FIG. 13, first, an X having a vacuum envelope 31, an anode 35, a cathode 36, high voltage insulating members 40 and 50, high voltage supply terminals 44 and 54, and a KOV member 55. A wire tube 30 is prepared.

  Next, the support member 25 is carried into the vacuum chamber 90 in which the jig 91 is accommodated.

  Here, the jig 91 has a housing 92 formed with one end closed. The housing 92 has a through hole 92h. In addition to the through hole 92h, the housing 92 may have a recess. An annular plate member 97 is fixed on the housing 92. The size of the plate member 97 corresponds to the size of the support member 25. The plate member 97 has a flat end surface 97a. The end face 97a is made of polytetrafluoroethylene.

  After carrying in the support member 25, the support member 25 is placed on the housing 92. Thereby, the support member 25 is fitted to the plate member 97 with almost no gap. The plate member 97 and the support member 25 form a mold material tank 96.

  Next, the stator coil 910 is carried into the vacuum chamber 90, and the stator coil 910 is placed on the housing 92. Subsequently, after the X-ray tube 30 is carried into the vacuum chamber 90, the X-ray tube 30 is placed on the housing 92. Here, the housing 92 supports the vacuum vessel 32. As a result, the end surface (adhesion surface) 41 of the high-voltage insulating member 40 is carried into the mold material tank 96, and the high-voltage supply terminal 44 is inserted into the opening of the plate member 97 and the through hole 92h. Note that the stator coil 910 is fitted into the high voltage insulating member 40.

  Subsequently, the pipe 98 for injecting the mold material is passed through the other through hole of the housing 92. Thereafter, the inside of the vacuum chamber 90 is evacuated. Next, a mold material is injected into the mold material tank 96 using the pipe 98. Note that by injecting in vacuum, it is possible to prevent bubbles such as air that may remain in the mold material from remaining.

  Thereafter, the injected molding material is cured to form an electrically insulating member 60 including a flat end surface 61, the other end surface 62 directly bonded to the end surface (adhesion surface) 41, and a through hole 63. The The electrically insulating member 60 is bonded to the support member 25 and the high voltage insulating member 40.

  After the inside of the vacuum chamber 90 is opened to the atmosphere, the pipe 98 is removed from the housing 92, and then the X-ray tube 30 provided with the stator coil 910, the electrical insulating member 60 and the support member 25 is removed from the housing 92. Thereby, the electrically insulating member 60 is peeled from the end surface 97a, and the flat end surface 61 of the electrically insulating member 60 is exposed.

  Then, as shown in FIG. 12, the housing 20 is prepared. Specifically, a housing body 20a having an opening is prepared. Next, the X-ray tube 30 provided with the stator coil 910, the electrically insulating member 60, and the support member 25 is accommodated in the housing body 20a. At this time, the end surface 41 is opposed to the opening of the housing 20 (annular portion 20 d), and the end surface 61 and the high voltage supply terminal 44 are exposed to the outside of the housing 20. The through hole 63 maintains the exposure of the high voltage supply terminal 44 to the outside of the housing 20.

  Subsequently, after attaching the support member 26 to the high-voltage insulating member 50, the annular portion 20b is screwed to the other end of the housing body 20a. Thereafter, the coolant 7 is filled between the X-ray tube 30 and the housing main body 20a. Thereby, the housing 20 that holds the coolant 7 in a liquid-tight manner is formed. Thereafter, the X-ray tube apparatus 10 is completed by attaching the high voltage connectors 100 and 200 to the housing 20.

  According to the X-ray tube apparatus 10 and the method for manufacturing the X-ray tube apparatus 10 according to the fifth embodiment configured as described above, the X-ray tube apparatus 10 includes the vacuum envelope 31 and the anode target 35a. An X-ray tube 30 having a cathode 36, a housing 20, a coolant 7, high-voltage insulating members 40 and 50, high-voltage supply terminals 44 and 54, and an electrical insulating member 60. ing.

  The electrically insulating member 60 includes a flat end surface 61 having an area larger than that of the end surface (bonding surface) 41, and the other end surface 62 bonded to the outer surface of the high voltage insulating member 40. In this embodiment, the diameter of the electrically insulating member 60 is larger than the diameter of the bottom 47. In the molding material injection process for forming the electrical insulating member 60, the stator coil 910 may be fitted in the high voltage insulating member 40 in advance.

  Thereby, the insulation of the connection part of the high voltage connector 100 can be ensured over a long period of time without being concerned with the size of the X-ray tube 30. Since it is not necessary to increase the diameters of the high-voltage insulating member 40 and the stator coil 910, an increase in weight and an increase in size of the X-ray tube device 10 (X-ray tube 30) can be suppressed.

  In this embodiment, since the electrical insulating member 60 is bonded not only to the end face (bonding surface) 41 but also to the side surface of the bottom portion 47, the high-voltage insulating member 40 and the electric insulating member 60 are compared to the first embodiment. The electrical insulation characteristics and adhesive strength between the electrical insulation members 60 can be improved.

Moreover, since the electrical insulating member 60 is directly bonded to the high voltage insulating member 40 without the adhesive 14, the high voltage insulating member 40 and the electrical insulating member 60 are compared with each other as compared with the first embodiment. It is possible to further improve the electrical insulation characteristics and adhesive strength.

In addition, the X-ray tube apparatus 10 of this embodiment can obtain the same effects as the X-ray tube apparatus 10 of the first embodiment described above.
From the above, an increase in weight and an increase in size can be suppressed, and a highly reliable X-ray tube device 10 and a method for manufacturing the X-ray tube device 10 can be obtained over a long period of time.

  Next, an X-ray tube apparatus 10 and a method for manufacturing the X-ray tube apparatus 10 according to a sixth embodiment of the present invention will be described. In this embodiment, the same reference numerals are given to the same functional portions as those in the fifth embodiment, and detailed description thereof will be omitted.

  As shown in FIG. 14, the X-ray tube apparatus 10 includes an electrically insulating member 70. The electrically insulating member 70 is fitted into the support member 25 and bonded to the support member 25. The electrically insulating member 70 is formed in an annular shape so as to keep the high voltage supply terminal 44 exposed to the outside of the housing 20. The electrically insulating member 70 is exposed to the outside of the housing 20 and includes a flat end surface 71 having an area larger than the end surface (adhesion surface) 41. The electrical insulating member 70 is formed of a ceramic material or a glass material, like the electrical insulating member 60.

  The electrically insulating member 60 includes an end surface 61, the other end surface 62, and a through hole 63. The electrically insulating member 60 is formed in a bottomed cylindrical shape having a larger outer diameter than the bottom portion 47. Specifically, the electrical insulating member 60 includes a cylindrical portion 66 having the other end surface 62, a disk-shaped bottom portion 67 that closes one end side of the cylindrical portion 66, and has the end surface 61, the other end surface 62, and the through hole 63. have.

The end surface 61 has a larger area than the end surface (adhesion surface) 41. The electrically insulating member 60 is formed of a molding material, and is directly bonded (permanently bonded) to the outer surface of the bottom 47, the support member 25, and the electrically insulating member 70. That is, the electrical insulating member 60 itself is formed of a material having adhesiveness. The support member 25 is formed longer than the electrically insulating member 60.
Examples of the molding material include a material mainly composed of an epoxy resin or a silicone resin.

Next, a method for manufacturing the X-ray tube apparatus 10 will be described.
As shown in FIG. 15, first, an X having a vacuum envelope 31, an anode 35, a cathode 36, high-voltage insulating members 40 and 50, high-voltage supply terminals 44 and 54, and a KOV member 55. A wire tube 30 is prepared.

  Next, the support member 25 to which the electrically insulating member 70 is attached is carried into the vacuum chamber 90 in which the jig 91 is accommodated. After carrying in the support member 25, the support member 25 is placed on the housing 92. The electrically insulating member 70 and the support member 25 form a mold material tank 96.

  Next, the stator coil 910 is carried into the vacuum chamber 90, and the stator coil 910 is placed on the housing 92. Subsequently, after the X-ray tube 30 is carried into the vacuum chamber 90, the X-ray tube 30 is placed on the housing 92. Here, the housing 92 supports the vacuum vessel 32. As a result, the end surface (adhesion surface) 41 of the high voltage insulating member 40 is carried into the mold material tank 96, and the high voltage supply terminal 44 is inserted into the opening of the electrical insulating member 70 and the through hole 92h. Note that the stator coil 910 is fitted into the high voltage insulating member 40.

  Subsequently, the pipe 98 for injecting the mold material is passed through the other through hole of the housing 92. Thereafter, the inside of the vacuum chamber 90 is evacuated. Next, a mold material is injected into the mold material tank 96 using the pipe 98.

  Thereafter, the injected molding material is cured to form an electrically insulating member 60 including an end surface 61, the other end surface 62 directly bonded to the end surface (adhesion surface) 41, and a through hole 63. The electrically insulating member 60 is bonded to the electrically insulating member 70, the support member 25, and the high voltage insulating member 40.

  After the inside of the vacuum chamber 90 is opened to the atmosphere, the pipe 98 is removed from the housing 92, and then the X-ray tube 30 provided with the stator coil 910, the electrically insulating members 60 and 70 and the support member 25 is removed from the housing 92. .

  As shown in FIG. 14, the housing 20 is then prepared. Specifically, a housing body 20a having an opening is prepared. Next, the X-ray tube 30 provided with the stator coil 910, the electrically insulating members 60 and 70, and the support member 25 is accommodated in the housing body 20a. At this time, the end surface 41 is opposed to the opening of the housing 20 (annular portion 20d), and the end surface 71 and the high voltage supply terminal 44 are exposed to the outside of the housing 20.

  Subsequently, after attaching the support member 26 to the high-voltage insulating member 50, the annular portion 20b is screwed to the other end of the housing body 20a. Thereafter, the coolant 7 is filled between the X-ray tube 30 and the housing main body 20a. Thereby, the housing 20 that holds the coolant 7 in a liquid-tight manner is formed. Thereafter, the X-ray tube apparatus 10 is completed by attaching the high voltage connectors 100 and 200 to the housing 20.

  According to the X-ray tube apparatus 10 and the method for manufacturing the X-ray tube apparatus 10 according to the sixth embodiment configured as described above, the X-ray tube apparatus 10 includes the vacuum envelope 31 and the anode target 35a. An X-ray tube 30 having a cathode 36, a housing 20, a coolant 7, high-voltage insulating members 40 and 50, high-voltage supply terminals 44 and 54, an electric insulating member 60, and electric insulation And a sex member 70.

  The electrically insulating member 60 includes an end surface 61 having an area larger than that of the end surface (bonding surface) 41, and the other end surface 62 bonded to the outer surface of the high voltage insulating member 40. In this embodiment, the diameter of the electrically insulating member 60 is larger than the diameter of the bottom 47. The electrically insulating member 70 includes a flat end surface 71 having an area larger than that of the end surface (adhesion surface) 41. In the molding material injection process for forming the electrical insulating member 60, the stator coil 910 may be fitted in the high voltage insulating member 40 in advance.

  Thereby, the insulation of the connection part of the high voltage connector 100 can be ensured over a long period of time without being concerned with the size of the X-ray tube 30. Since it is not necessary to increase the diameters of the high-voltage insulating member 40 and the stator coil 910, an increase in weight and an increase in size of the X-ray tube device 10 (X-ray tube 30) can be suppressed.

  By improving the flatness of the end surface 71 of the electrical insulating member 70, the electrical insulating member 70 can have the end surface 71 excellent in flatness in advance. For this reason, the flatness of the end surface 71 is higher than the flatness of the end surface 61 of the said 5th Embodiment formed with the mold material. Compared with the case where the high voltage connector 100 is brought into close contact with the end face 61 of the fifth embodiment, the discharge along the contact interface can be suppressed when the high voltage connector 100 is brought into close contact with the electrical insulating member 70.

  In this embodiment, since the electrical insulating member 60 is bonded not only to the end face (bonding surface) 41 but also to the side surface of the bottom portion 47, the high-voltage insulating member 40 and the electric insulating member 60 are compared to the first embodiment. The electrical insulation characteristics and adhesive strength between the electrical insulation members 60 can be improved.

Moreover, since the electrical insulating member 60 is directly bonded to the high voltage insulating member 40 without the adhesive 14, the high voltage insulating member 40 and the electrical insulating member 60 are compared with each other as compared with the first embodiment. It is possible to further improve the electrical insulation characteristics and adhesive strength.

In addition, the X-ray tube apparatus 10 of this embodiment can obtain the same effects as the X-ray tube apparatus 10 of the first embodiment described above.
From the above, an increase in weight and an increase in size can be suppressed, and a highly reliable X-ray tube device 10 and a method for manufacturing the X-ray tube device 10 can be obtained over a long period of time.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the components without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiments. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  For example, when bonding the high-voltage insulating member 40 and the electrical insulating member 60 using the adhesive 14 or when injecting a molding material, it is desirable to carry out in a vacuum. You may implement.

  The method and configuration for pressing the electrical insulating member 60 for bonding the electrical insulating member 60 to the high voltage insulating member 40 are not limited to the above-described method and configuration, and can be variously modified. The method and configuration for injecting the mold material into the mold material tank 96 are not limited to the method and configuration described above, and can be variously modified.

  The member for connecting the high voltage supply terminal 44 and the support 35b is not limited to the metallized layer 11 and can be variously modified and configured to connect the high voltage supply terminal 44 and the support 35b. It ’s fine.

  When the electric insulating member 60 is bonded to the high voltage insulating member 40 and the electric insulating member 70 via an adhesive, a pre-treatment for improving the bonding strength is performed on at least one of the bonding surfaces of the respective members. Also good. A known primer coating can be employed as the pretreatment.

  Although the electrical insulating member 60 is bonded to the high voltage insulating member 40 to which the anode 35 is attached, the electrical insulating member may be bonded to the high voltage insulating member 50 to which the cathode 36 is attached.

As shown in FIG. 16, for example, the X-ray tube apparatus 10 includes an electrically insulating member 80 and a support 36b. The electrically insulating member 80 is formed in a disk shape having an outer diameter larger than that of the bottom portion 57. The electrically insulating member 80 includes an end surface 81, the other end surface 82, and a through hole 83. The end surface 81 is exposed to the outside of the housing 20 and has a larger area than the end surface 51. The end surface 81 is a flat surface. The other end surface 82 has a larger area than the end surface 51. The through hole 83 opens in the end surface 81 and the other end surface 82. The through hole 83 maintains the exposure of the high voltage supply terminal 54 to the outside of the housing 20. The other end surface 82 is bonded (permanently bonded) to the end surface (bonded surface) 51 via the adhesive 14.
The electrical insulating member 80 is formed of a ceramic material or a glass material, similarly to the electrical insulating member 60.

The support 36b is positioned at a distance from the bottom 57. The support body 36 b includes a joint portion 36 c joined to the inner surface of the cylindrical portion 56, is located inside the vacuum envelope 31, and supports the cathode 36. The joining portion 36c exhibits flexibility. For this reason, the joining part 36c is elastically deformed at a high temperature to relieve at least a part of the thermal stress. The KOV member 55 and the support 36b are brazed.
The present invention is not limited to the X-ray tube device 10 and the method for manufacturing the X-ray tube device 10 but can be applied to various X-ray tube devices and methods for manufacturing the same.

  DESCRIPTION OF SYMBOLS 1 ... Fixed body, 2 ... Rotating body, 7 ... Coolant, 10 ... X-ray tube apparatus, 11 ... Metallization layer, 14 ... Adhesive, 16 ... Heat transfer promotion part, 16a ... Convex part, 20 ... Housing, 20a ... Housing body, 20b, 20d ... annular part, 20c ... cylindrical part, 22 ... coolant circulating pump, 23 ... heat exchanger, 24, 33 ... radiation window, 25, 26 ... support member, 30 ... X-ray tube, 31 ... Vacuum envelope, 32 ... Vacuum container, 35 ... Anode, 35a ... Anode target, 35b ... Support, 35c ... Junction, 35d ... Rough surface, 36 ... Cathode, 36b ... Support, 36c ... Joint, 40 50, high voltage insulating member, 41, 51 ... end face, 43, 53 ... heat transfer surface, 44, 54 ... high voltage supply terminal, 60, 70, 80 ... electrical insulating member, 61, 71, 81 ... end face, 62, 82 ... other end surface, 63, 83 ... through hole, 90 ... vacuum chamber DESCRIPTION OF SYMBOLS 91 ... Jig, 92 ... Housing, 92h ... Through-hole, 93 ... Support member, 94 ... Elevating mechanism, 96 ... Mold material tank, 100, 200 ... High voltage connector, 103, 203 ... Electrical insulation material, 104, 204 ... Silicone plate.

Claims (21)

An X-ray tube comprising: a vacuum envelope; an anode target provided in the vacuum envelope; and a cathode provided in the vacuum envelope and emitting electrons that irradiate the anode target.
A housing having an opening and containing the X-ray tube;
A coolant filled between the X-ray tube and the housing;
A heat transfer surface that directly or indirectly contacts the coolant and transfers heat to the coolant, and an adhesive surface that faces the opening of the housing, and constitutes a part of the vacuum envelope; A high voltage insulating member to which the anode target or cathode is attached, and
A high voltage supply terminal provided on the high voltage insulating member and exposed to the outside of the housing;
A flat end surface exposed to the outside of the housing and having an area larger than the bonding surface; the other end surface bonded to the bonding surface of the high voltage insulating member; and the high voltage supply terminal to the outside of the housing. An X-ray tube apparatus comprising: an electrically insulating member including a through hole that opens to the end surface and the other end surface so as to maintain exposure.   The X-ray tube apparatus according to claim 1, further comprising a high-voltage connector that includes an electric insulating material that is directly or indirectly adhered to an end surface of the electric insulating member, and that applies a high voltage to the high-voltage supply terminal. .   The X-ray tube apparatus according to claim 1, wherein the electrically insulating member is formed of a ceramic material and is bonded to an adhesive surface of the high voltage insulating member via an adhesive.   The X-ray tube apparatus according to claim 1, wherein the electrically insulating member is formed of a glass material and is bonded to an adhesive surface of the high voltage insulating member via an adhesive.   The X-ray tube apparatus according to claim 1, wherein the electrically insulating member is formed of a molding material and is directly bonded to a bonding surface of the high voltage insulating member. A seal part for preventing the coolant 7 from entering the adhesive interface between the adhesive surface and the other end surface;
The X-ray tube apparatus according to claim 1, wherein the bonding surface is located inside the housing.   The X-ray tube apparatus according to claim 1, wherein the adhesive surface is located outside the housing.   The X-ray tube apparatus according to claim 1, wherein the coolant is an aqueous coolant. Further comprising a support located inside the vacuum envelope and supporting the anode target;
The high-voltage insulating member includes a cylindrical portion having the heat transfer surface, and a bottom portion having one end side of the cylindrical portion closed and having the adhesive surface,
The X-ray tube apparatus according to any one of claims 1 to 8, wherein the support body includes a joint portion joined to an inner surface of the cylindrical portion. A metallized layer formed on the inner surface of the high-voltage insulating member and connected to the joint;
The X-ray tube apparatus according to claim 9, wherein the high voltage supply terminal is connected to the metallized layer through a part of the bottom. A support body that is located inside the vacuum envelope and supports the cathode;
The high-voltage insulating member includes a cylindrical portion having the heat transfer surface, and a bottom portion having one end side of the cylindrical portion closed and having the adhesive surface,
The X-ray tube apparatus according to any one of claims 1 to 8, wherein the support body includes a joint portion joined to an inner surface of the cylindrical portion.   The X-ray tube apparatus according to claim 9 or 11, wherein the joint portion exhibits flexibility, elastically deforms at a high temperature, and relieves at least a part of thermal stress. The joining portion has an uneven surface facing the inner surface of the cylindrical portion,
The X-ray tube apparatus according to claim 12, wherein a convex portion of the joint portion is joined to an inner surface of the cylindrical portion.   The X-ray tube according to claim 9 or 11, wherein the support is joined to an inner surface of the high-voltage insulating member via a flexible component that is elastically deformed at a high temperature and relaxes at least a part of thermal stress.   The X-ray tube apparatus according to any one of claims 1 to 14, wherein the high-voltage insulating member further includes a heat transfer promoting portion provided on the heat transfer surface and in contact with the coolant.   The X-ray tube apparatus according to claim 15, wherein the heat transfer promoting part is a concavo-convex pattern formed on a surface of the high-voltage insulating member itself.   The X-ray tube apparatus according to claim 15, wherein the heat transfer promoting part is a metal member joined to the heat transfer surface.   18. The X-ray tube apparatus according to claim 1, further comprising a coolant circulation pump that is connected to the housing and creates a flow of the coolant in the housing.   The X-ray tube apparatus according to claim 18, further comprising a heat exchanger connected between the housing and the coolant circulation pump and releasing heat of the coolant to the outside. A vacuum envelope, an anode target provided in the vacuum envelope, a cathode provided in the vacuum envelope and emitting electrons to be irradiated to the anode target, a heat transfer surface and an adhesive surface An X-ray comprising a high-voltage insulating member that constitutes a part of the vacuum envelope and to which the anode target or the cathode is attached in a vacuum, and a high-voltage supply terminal provided on the high-voltage insulating member Prepare a tube,
Preparing an electrically insulating member including a flat end surface having an area larger than the adhesive surface, the other end surface, and a through hole opening in the end surface and the other end surface;
Applying an adhesive to at least one of the adhesive surface and the other end surface;
The other end surface is brought into contact with the adhesive surface through the adhesive,
After the contact, press the electrical insulating member, adhere the electrical insulating member to the high voltage insulating member,
Prepare a housing with an opening,
The X-ray tube provided with the electrically insulating member is accommodated in the housing, the adhesive surface is opposed to the opening, the end surface and the high voltage supply terminal are exposed to the outside of the housing, and the through hole Maintains exposure of the high voltage supply terminal to the outside of the housing;
A method of manufacturing an X-ray tube apparatus, wherein a coolant is filled between the X-ray tube and the housing. A vacuum envelope, an anode target provided in the vacuum envelope, a cathode provided in the vacuum envelope and emitting electrons to be irradiated to the anode target, a heat transfer surface and an adhesive surface An X-ray comprising a high-voltage insulating member that constitutes a part of the vacuum envelope and to which the anode target or the cathode is attached in a vacuum, and a high-voltage supply terminal provided on the high-voltage insulating member Prepare a tube,
The adhesive surface of the high voltage insulating member is carried into the mold material tank, and the high voltage supply terminal is inserted into a through hole or a recess formed in the mold material tank.
Injecting mold material into the mold material tank,
The injected mold material is cured, a flat end surface having an area larger than the bonding surface, the other end surface directly bonded to the bonding surface, and the high voltage supply terminal are surrounded and opened to the end surface and the other end surface. And forming an electrically insulating member including a through hole,
Prepare a housing with an opening,
The X-ray tube provided with the electrically insulating member is accommodated in the housing, the adhesive surface is opposed to the opening, the end surface and the high voltage supply terminal are exposed to the outside of the housing, and the electrical insulation is performed. The through hole of the conductive member maintains the exposure of the high voltage supply terminal to the outside of the housing;
A method of manufacturing an X-ray tube apparatus, wherein a coolant is filled between the X-ray tube and the housing.

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